/* Server CLI (command line interface)
 *
 * Copyright (c) 2009-2012, Salvatore Sanfilippo <antirez at gmail dot com>
 * All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions are met:
 *
 *   * Redistributions of source code must retain the above copyright notice,
 *     this list of conditions and the following disclaimer.
 *   * Redistributions in binary form must reproduce the above copyright
 *     notice, this list of conditions and the following disclaimer in the
 *     documentation and/or other materials provided with the distribution.
 *   * Neither the name of Redis nor the names of its contributors may be used
 *     to endorse or promote products derived from this software without
 *     specific prior written permission.
 *
 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
 * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
 * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 * POSSIBILITY OF SUCH DAMAGE.
 */

#include "fmacros.h"

#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <signal.h>
#include <unistd.h>
#include <time.h>
#include <ctype.h>
#include <errno.h>
#include <sys/stat.h>
#include <sys/time.h>
#include <assert.h>
#include <fcntl.h>
#include <limits.h>
#include <math.h>
#include <termios.h>

#include <hiredis.h>
#ifdef USE_OPENSSL
#include <openssl/ssl.h>
#include <openssl/err.h>
#include <hiredis_ssl.h>
#endif
#include <sdscompat.h> /* Use hiredis' sds compat header that maps sds calls to their hi_ variants */
#include <sds.h>       /* use sds.h from hiredis, so that only one set of sds functions will be present in the binary */
#include "dict.h"
#include "adlist.h"
#include "zmalloc.h"
#include "linenoise.h"
#include "anet.h"
#include "ae.h"
#include "connection.h"
#include "cli_common.h"
#include "mt19937-64.h"
#include "cli_commands.h"

#define UNUSED(V) ((void)V)

#define OUTPUT_STANDARD 0
#define OUTPUT_RAW 1
#define OUTPUT_CSV 2
#define OUTPUT_JSON 3
#define OUTPUT_QUOTED_JSON 4
#define CLI_KEEPALIVE_INTERVAL 15   /* seconds */
#define CLI_DEFAULT_PIPE_TIMEOUT 30 /* seconds */
#define CLI_HISTFILE_ENV "REDISCLI_HISTFILE"
#define CLI_HISTFILE_DEFAULT ".valkeycli_history"
#define CLI_RCFILE_ENV "REDISCLI_RCFILE"
#define CLI_RCFILE_DEFAULT ".valkeyclirc"
#define CLI_AUTH_ENV "REDISCLI_AUTH"
#define CLI_CLUSTER_YES_ENV "REDISCLI_CLUSTER_YES"

#define CLUSTER_MANAGER_SLOTS 16384
#define CLUSTER_MANAGER_PORT_INCR 10000 /* same as CLUSTER_PORT_INCR */
#define CLUSTER_MANAGER_MIGRATE_TIMEOUT 60000
#define CLUSTER_MANAGER_MIGRATE_PIPELINE 10
#define CLUSTER_MANAGER_REBALANCE_THRESHOLD 2

#define CLUSTER_MANAGER_INVALID_HOST_ARG                                                                               \
    "[ERR] Invalid arguments: you need to pass either a valid "                                                        \
    "address (ie. 120.0.0.1:7000) or space separated IP "                                                              \
    "and port (ie. 120.0.0.1 7000)\n"
#define CLUSTER_MANAGER_MODE() (config.cluster_manager_command.name != NULL)
#define CLUSTER_MANAGER_PRIMARIES_COUNT(nodes, replicas) ((nodes) / ((replicas) + 1))
#define CLUSTER_MANAGER_COMMAND(n, ...) (redisCommand((n)->context, __VA_ARGS__))

#define CLUSTER_MANAGER_NODE_ARRAY_FREE(array) zfree((array)->alloc)

#define CLUSTER_MANAGER_PRINT_REPLY_ERROR(n, err)                                                                      \
    clusterManagerLogErr("Node %s:%d replied with error:\n%s\n", (n)->ip, (n)->port, (err));

#define clusterManagerLogInfo(...) clusterManagerLog(CLUSTER_MANAGER_LOG_LVL_INFO, __VA_ARGS__)

#define clusterManagerLogErr(...) clusterManagerLog(CLUSTER_MANAGER_LOG_LVL_ERR, __VA_ARGS__)

#define clusterManagerLogWarn(...) clusterManagerLog(CLUSTER_MANAGER_LOG_LVL_WARN, __VA_ARGS__)

#define clusterManagerLogOk(...) clusterManagerLog(CLUSTER_MANAGER_LOG_LVL_SUCCESS, __VA_ARGS__)

#define CLUSTER_MANAGER_FLAG_MYSELF 1 << 0
#define CLUSTER_MANAGER_FLAG_REPLICA 1 << 1
#define CLUSTER_MANAGER_FLAG_FRIEND 1 << 2
#define CLUSTER_MANAGER_FLAG_NOADDR 1 << 3
#define CLUSTER_MANAGER_FLAG_DISCONNECT 1 << 4
#define CLUSTER_MANAGER_FLAG_FAIL 1 << 5

#define CLUSTER_MANAGER_CMD_FLAG_FIX 1 << 0
#define CLUSTER_MANAGER_CMD_FLAG_REPLICA 1 << 1
#define CLUSTER_MANAGER_CMD_FLAG_YES 1 << 2
#define CLUSTER_MANAGER_CMD_FLAG_AUTOWEIGHTS 1 << 3
#define CLUSTER_MANAGER_CMD_FLAG_EMPTY_PRIMARY 1 << 4
#define CLUSTER_MANAGER_CMD_FLAG_SIMULATE 1 << 5
#define CLUSTER_MANAGER_CMD_FLAG_REPLACE 1 << 6
#define CLUSTER_MANAGER_CMD_FLAG_COPY 1 << 7
#define CLUSTER_MANAGER_CMD_FLAG_COLOR 1 << 8
#define CLUSTER_MANAGER_CMD_FLAG_CHECK_OWNERS 1 << 9
#define CLUSTER_MANAGER_CMD_FLAG_FIX_WITH_UNREACHABLE_PRIMARIES 1 << 10
#define CLUSTER_MANAGER_CMD_FLAG_PRIMARIES_ONLY 1 << 11
#define CLUSTER_MANAGER_CMD_FLAG_REPLICAS_ONLY 1 << 12

#define CLUSTER_MANAGER_OPT_GETFRIENDS 1 << 0
#define CLUSTER_MANAGER_OPT_COLD 1 << 1
#define CLUSTER_MANAGER_OPT_UPDATE 1 << 2
#define CLUSTER_MANAGER_OPT_QUIET 1 << 6
#define CLUSTER_MANAGER_OPT_VERBOSE 1 << 7

#define CLUSTER_MANAGER_LOG_LVL_INFO 1
#define CLUSTER_MANAGER_LOG_LVL_WARN 2
#define CLUSTER_MANAGER_LOG_LVL_ERR 3
#define CLUSTER_MANAGER_LOG_LVL_SUCCESS 4

#define CLUSTER_JOIN_CHECK_AFTER 20

#define LOG_COLOR_BOLD "29;1m"
#define LOG_COLOR_RED "31;1m"
#define LOG_COLOR_GREEN "32;1m"
#define LOG_COLOR_YELLOW "33;1m"
#define LOG_COLOR_RESET "0m"

/* cliConnect() flags. */
#define CC_FORCE (1 << 0) /* Re-connect if already connected. */
#define CC_QUIET (1 << 1) /* Don't log connecting errors. */

/* DNS lookup */
#define NET_IP_STR_LEN 46 /* INET6_ADDRSTRLEN is 46 */

/* --latency-dist palettes. */
int spectrum_palette_color_size = 19;
int spectrum_palette_color[] = {0,   233, 234, 235, 237, 239, 241, 243, 245, 247,
                                144, 143, 142, 184, 226, 214, 208, 202, 196};

int spectrum_palette_mono_size = 13;
int spectrum_palette_mono[] = {0, 233, 234, 235, 237, 239, 241, 243, 245, 247, 249, 251, 253};

/* The actual palette in use. */
int *spectrum_palette;
int spectrum_palette_size;

static int orig_termios_saved = 0;
static struct termios orig_termios; /* To restore terminal at exit.*/

/* Dict Helpers */
static uint64_t dictSdsHash(const void *key);
static int dictSdsKeyCompare(dict *d, const void *key1, const void *key2);
static void dictSdsDestructor(dict *d, void *val);
static void dictListDestructor(dict *d, void *val);

/* Cluster Manager Command Info */
typedef struct clusterManagerCommand {
    char *name;
    int argc;
    char **argv;
    sds stdin_arg; /* arg from stdin. (-X option) */
    int flags;
    int replicas;
    char *from;
    char *to;
    char **weight;
    int weight_argc;
    char *primary_id;
    int slots;
    int timeout;
    int pipeline;
    float threshold;
    char *backup_dir;
    char *from_user;
    char *from_pass;
    int from_askpass;
} clusterManagerCommand;

static int createClusterManagerCommand(char *cmdname, int argc, char **argv);


static redisContext *context;
static struct config {
    cliConnInfo conn_info;
    struct timeval connect_timeout;
    char *hostsocket;
    int tls;
    cliSSLconfig sslconfig;
    long repeat;
    long interval;
    int dbnum; /* db num currently selected */
    int interactive;
    int shutdown;
    int monitor_mode;
    int pubsub_mode;
    int blocking_state_aborted; /* used to abort monitor_mode and pubsub_mode. */
    int latency_mode;
    int latency_dist_mode;
    int latency_history;
    int lru_test_mode;
    long long lru_test_sample_size;
    int cluster_mode;
    int cluster_reissue_command;
    int cluster_send_asking;
    int replica_mode;
    int pipe_mode;
    int pipe_timeout;
    int getrdb_mode;
    int get_functions_rdb_mode;
    int stat_mode;
    int scan_mode;
    int count;
    int intrinsic_latency_mode;
    int intrinsic_latency_duration;
    sds pattern;
    char *rdb_filename;
    int bigkeys;
    int memkeys;
    unsigned memkeys_samples;
    int hotkeys;
    int stdin_lastarg;    /* get last arg from stdin. (-x option) */
    int stdin_tag_arg;    /* get <tag> arg from stdin. (-X option) */
    char *stdin_tag_name; /* Placeholder(tag name) for user input. */
    int askpass;
    int quoted_input; /* Force input args to be treated as quoted strings */
    int output;       /* output mode, see OUTPUT_* defines */
    int push_output;  /* Should we display spontaneous PUSH replies */
    sds mb_delim;
    sds cmd_delim;
    char prompt[128];
    char *eval;
    int eval_ldb;
    int eval_ldb_sync;      /* Ask for synchronous mode of the Lua debugger. */
    int eval_ldb_end;       /* Lua debugging session ended. */
    int enable_ldb_on_eval; /* Handle manual SCRIPT DEBUG + EVAL commands. */
    int last_cmd_type;
    redisReply *last_reply;
    int verbose;
    int set_errcode;
    clusterManagerCommand cluster_manager_command;
    int no_auth_warning;
    int resp2;         /* value of 1: specified explicitly with option -2 */
    int resp3;         /* value of 1: specified explicitly, value of 2: implicit like --json option */
    int current_resp3; /* 1 if we have RESP3 right now in the current connection. */
    int in_multi;
    int pre_multi_dbnum;
    char *server_version;
    char *test_hint;
    char *test_hint_file;
    int prefer_ipv4; /* Prefer IPv4 over IPv6 on DNS lookup. */
    int prefer_ipv6; /* Prefer IPv6 over IPv4 on DNS lookup. */
} config;

/* User preferences. */
static struct pref {
    int hints;
} pref;

static volatile sig_atomic_t force_cancel_loop = 0;
static void usage(int err);
static void replicaMode(int send_sync);
static int cliConnect(int flags);

static char *getInfoField(char *info, char *field);
static long getLongInfoField(char *info, char *field);

/*------------------------------------------------------------------------------
 * Utility functions
 *--------------------------------------------------------------------------- */
size_t valkey_strlcpy(char *dst, const char *src, size_t dsize);

static void cliPushHandler(void *, void *);

uint16_t crc16(const char *buf, int len);

static long long ustime(void) {
    struct timeval tv;
    long long ust;

    gettimeofday(&tv, NULL);
    ust = ((long long)tv.tv_sec) * 1000000;
    ust += tv.tv_usec;
    return ust;
}

static long long mstime(void) {
    return ustime() / 1000;
}

static void cliRefreshPrompt(void) {
    if (config.eval_ldb) return;

    sds prompt = sdsempty();
    if (config.hostsocket != NULL) {
        prompt = sdscatfmt(prompt, "valkey %s", config.hostsocket);
    } else {
        char addr[256];
        formatAddr(addr, sizeof(addr), config.conn_info.hostip, config.conn_info.hostport);
        prompt = sdscatlen(prompt, addr, strlen(addr));
    }

    /* Add [dbnum] if needed */
    if (config.dbnum != 0) prompt = sdscatfmt(prompt, "[%i]", config.dbnum);

    /* Add TX if in transaction state*/
    if (config.in_multi) prompt = sdscatlen(prompt, "(TX)", 4);

    if (config.pubsub_mode) prompt = sdscatfmt(prompt, "(subscribed mode)");

    /* Copy the prompt in the static buffer. */
    prompt = sdscatlen(prompt, "> ", 2);
    snprintf(config.prompt, sizeof(config.prompt), "%s", prompt);
    sdsfree(prompt);
}

/* Return the name of the dotfile for the specified 'dotfilename'.
 * Normally it just concatenates user $HOME to the file specified
 * in 'dotfilename'. However if the environment variable 'envoverride'
 * is set, its value is taken as the path.
 *
 * The function returns NULL (if the file is /dev/null or cannot be
 * obtained for some error), or an SDS string that must be freed by
 * the user. */
static sds getDotfilePath(char *envoverride, char *dotfilename) {
    char *path = NULL;
    sds dotPath = NULL;

    /* Check the env for a dotfile override. */
    path = getenv(envoverride);
    if (path != NULL && *path != '\0') {
        if (!strcmp("/dev/null", path)) {
            return NULL;
        }

        /* If the env is set, return it. */
        dotPath = sdsnew(path);
    } else {
        char *home = getenv("HOME");
        if (home != NULL && *home != '\0') {
            /* If no override is set use $HOME/<dotfilename>. */
            dotPath = sdscatprintf(sdsempty(), "%s/%s", home, dotfilename);
        }
    }
    return dotPath;
}

static uint64_t dictSdsHash(const void *key) {
    return dictGenHashFunction((unsigned char *)key, sdslen((char *)key));
}

static int dictSdsKeyCompare(dict *d, const void *key1, const void *key2) {
    int l1, l2;
    UNUSED(d);

    l1 = sdslen((sds)key1);
    l2 = sdslen((sds)key2);
    if (l1 != l2) return 0;
    return memcmp(key1, key2, l1) == 0;
}

static void dictSdsDestructor(dict *d, void *val) {
    UNUSED(d);
    sdsfree(val);
}

void dictListDestructor(dict *d, void *val) {
    UNUSED(d);
    listRelease((list *)val);
}

/*------------------------------------------------------------------------------
 * Help functions
 *--------------------------------------------------------------------------- */

#define CLI_HELP_COMMAND 1
#define CLI_HELP_GROUP 2

typedef struct {
    int type;
    int argc;
    sds *argv;
    sds full;

    /* Only used for help on commands */
    struct commandDocs docs;
} helpEntry;

static helpEntry *helpEntries = NULL;
static int helpEntriesLen = 0;

/* For backwards compatibility with pre-7.0 servers.
 * cliLegacyInitHelp() sets up the helpEntries array with the command and group
 * names from the commands.c file. However the server instance we are connecting
 * to may support more commands, so this function integrates the previous
 * entries with additional entries obtained using the COMMAND command
 * available in recent versions of the server. */
static void cliLegacyIntegrateHelp(void) {
    if (cliConnect(CC_QUIET) == REDIS_ERR) return;

    redisReply *reply = redisCommand(context, "COMMAND");
    if (reply == NULL || reply->type != REDIS_REPLY_ARRAY) return;

    /* Scan the array reported by COMMAND and fill only the entries that
     * don't already match what we have. */
    for (size_t j = 0; j < reply->elements; j++) {
        redisReply *entry = reply->element[j];
        if (entry->type != REDIS_REPLY_ARRAY || entry->elements < 4 || entry->element[0]->type != REDIS_REPLY_STRING ||
            entry->element[1]->type != REDIS_REPLY_INTEGER || entry->element[3]->type != REDIS_REPLY_INTEGER)
            return;
        char *cmdname = entry->element[0]->str;
        int i;

        for (i = 0; i < helpEntriesLen; i++) {
            helpEntry *he = helpEntries + i;
            if (!strcasecmp(he->argv[0], cmdname)) break;
        }
        if (i != helpEntriesLen) continue;

        helpEntriesLen++;
        helpEntries = zrealloc(helpEntries, sizeof(helpEntry) * helpEntriesLen);
        helpEntry *new = helpEntries + (helpEntriesLen - 1);

        new->argc = 1;
        new->argv = zmalloc(sizeof(sds));
        new->argv[0] = sdsnew(cmdname);
        new->full = new->argv[0];
        new->type = CLI_HELP_COMMAND;
        sdstoupper(new->argv[0]);

        new->docs.name = new->argv[0];
        new->docs.args = NULL;
        new->docs.numargs = 0;
        new->docs.params = sdsempty();
        int args = llabs(entry->element[1]->integer);
        args--; /* Remove the command name itself. */
        if (entry->element[3]->integer == 1) {
            new->docs.params = sdscat(new->docs.params, "key ");
            args--;
        }
        while (args-- > 0) new->docs.params = sdscat(new->docs.params, "arg ");
        if (entry->element[1]->integer < 0) new->docs.params = sdscat(new->docs.params, "...options...");
        new->docs.summary = "Help not available";
        new->docs.since = "Not known";
        new->docs.group = "generic";
    }
    freeReplyObject(reply);
}

/* Concatenate a string to an sds string, but if it's empty substitute double quote marks. */
static sds sdscat_orempty(sds params, const char *value) {
    if (value[0] == '\0') {
        return sdscat(params, "\"\"");
    }
    return sdscat(params, value);
}

static sds makeHint(char **inputargv, int inputargc, int cmdlen, struct commandDocs docs);

static void cliAddCommandDocArg(cliCommandArg *cmdArg, redisReply *argMap);

static void cliMakeCommandDocArgs(redisReply *arguments, cliCommandArg *result) {
    for (size_t j = 0; j < arguments->elements; j++) {
        cliAddCommandDocArg(&result[j], arguments->element[j]);
    }
}

static void cliAddCommandDocArg(cliCommandArg *cmdArg, redisReply *argMap) {
    if (argMap->type != REDIS_REPLY_MAP && argMap->type != REDIS_REPLY_ARRAY) {
        return;
    }

    for (size_t i = 0; i < argMap->elements; i += 2) {
        assert(argMap->element[i]->type == REDIS_REPLY_STRING);
        char *key = argMap->element[i]->str;
        if (!strcmp(key, "name")) {
            assert(argMap->element[i + 1]->type == REDIS_REPLY_STRING);
            cmdArg->name = sdsnew(argMap->element[i + 1]->str);
        } else if (!strcmp(key, "display_text")) {
            assert(argMap->element[i + 1]->type == REDIS_REPLY_STRING);
            cmdArg->display_text = sdsnew(argMap->element[i + 1]->str);
        } else if (!strcmp(key, "token")) {
            assert(argMap->element[i + 1]->type == REDIS_REPLY_STRING);
            cmdArg->token = sdsnew(argMap->element[i + 1]->str);
        } else if (!strcmp(key, "type")) {
            assert(argMap->element[i + 1]->type == REDIS_REPLY_STRING);
            char *type = argMap->element[i + 1]->str;
            if (!strcmp(type, "string")) {
                cmdArg->type = ARG_TYPE_STRING;
            } else if (!strcmp(type, "integer")) {
                cmdArg->type = ARG_TYPE_INTEGER;
            } else if (!strcmp(type, "double")) {
                cmdArg->type = ARG_TYPE_DOUBLE;
            } else if (!strcmp(type, "key")) {
                cmdArg->type = ARG_TYPE_KEY;
            } else if (!strcmp(type, "pattern")) {
                cmdArg->type = ARG_TYPE_PATTERN;
            } else if (!strcmp(type, "unix-time")) {
                cmdArg->type = ARG_TYPE_UNIX_TIME;
            } else if (!strcmp(type, "pure-token")) {
                cmdArg->type = ARG_TYPE_PURE_TOKEN;
            } else if (!strcmp(type, "oneof")) {
                cmdArg->type = ARG_TYPE_ONEOF;
            } else if (!strcmp(type, "block")) {
                cmdArg->type = ARG_TYPE_BLOCK;
            }
        } else if (!strcmp(key, "arguments")) {
            redisReply *arguments = argMap->element[i + 1];
            cmdArg->subargs = zcalloc(arguments->elements * sizeof(cliCommandArg));
            cmdArg->numsubargs = arguments->elements;
            cliMakeCommandDocArgs(arguments, cmdArg->subargs);
        } else if (!strcmp(key, "flags")) {
            redisReply *flags = argMap->element[i + 1];
            assert(flags->type == REDIS_REPLY_SET || flags->type == REDIS_REPLY_ARRAY);
            for (size_t j = 0; j < flags->elements; j++) {
                assert(flags->element[j]->type == REDIS_REPLY_STATUS);
                char *flag = flags->element[j]->str;
                if (!strcmp(flag, "optional")) {
                    cmdArg->flags |= CMD_ARG_OPTIONAL;
                } else if (!strcmp(flag, "multiple")) {
                    cmdArg->flags |= CMD_ARG_MULTIPLE;
                } else if (!strcmp(flag, "multiple_token")) {
                    cmdArg->flags |= CMD_ARG_MULTIPLE_TOKEN;
                }
            }
        }
    }
}

/* Fill in the fields of a help entry for the command/subcommand name. */
static void cliFillInCommandHelpEntry(helpEntry *help, char *cmdname, char *subcommandname) {
    help->argc = subcommandname ? 2 : 1;
    help->argv = zmalloc(sizeof(sds) * help->argc);
    help->argv[0] = sdsnew(cmdname);
    sdstoupper(help->argv[0]);
    if (subcommandname) {
        /* Subcommand name may be two words separated by a pipe character. */
        char *pipe = strchr(subcommandname, '|');
        if (pipe != NULL) {
            help->argv[1] = sdsnew(pipe + 1);
        } else {
            help->argv[1] = sdsnew(subcommandname);
        }
        sdstoupper(help->argv[1]);
    }
    sds fullname = sdsnew(help->argv[0]);
    if (subcommandname) {
        fullname = sdscat(fullname, " ");
        fullname = sdscat(fullname, help->argv[1]);
    }
    help->full = fullname;
    help->type = CLI_HELP_COMMAND;

    help->docs.name = help->full;
    help->docs.params = NULL;
    help->docs.args = NULL;
    help->docs.numargs = 0;
    help->docs.since = NULL;
}

/* Initialize a command help entry for the command/subcommand described in 'specs'.
 * 'next' points to the next help entry to be filled in.
 * 'groups' is a set of command group names to be filled in.
 * Returns a pointer to the next available position in the help entries table.
 * If the command has subcommands, this is called recursively for the subcommands.
 */
static helpEntry *
cliInitCommandHelpEntry(char *cmdname, char *subcommandname, helpEntry *next, redisReply *specs, dict *groups) {
    helpEntry *help = next++;
    cliFillInCommandHelpEntry(help, cmdname, subcommandname);

    assert(specs->type == REDIS_REPLY_MAP || specs->type == REDIS_REPLY_ARRAY);
    for (size_t j = 0; j < specs->elements; j += 2) {
        assert(specs->element[j]->type == REDIS_REPLY_STRING);
        char *key = specs->element[j]->str;
        if (!strcmp(key, "summary")) {
            redisReply *reply = specs->element[j + 1];
            assert(reply->type == REDIS_REPLY_STRING);
            help->docs.summary = sdsnew(reply->str);
        } else if (!strcmp(key, "since")) {
            redisReply *reply = specs->element[j + 1];
            assert(reply->type == REDIS_REPLY_STRING);
            help->docs.since = sdsnew(reply->str);
        } else if (!strcmp(key, "group")) {
            redisReply *reply = specs->element[j + 1];
            assert(reply->type == REDIS_REPLY_STRING);
            help->docs.group = sdsnew(reply->str);
            sds group = sdsdup(help->docs.group);
            if (dictAdd(groups, group, NULL) != DICT_OK) {
                sdsfree(group);
            }
        } else if (!strcmp(key, "arguments")) {
            redisReply *arguments = specs->element[j + 1];
            assert(arguments->type == REDIS_REPLY_ARRAY);
            help->docs.args = zcalloc(arguments->elements * sizeof(cliCommandArg));
            help->docs.numargs = arguments->elements;
            cliMakeCommandDocArgs(arguments, help->docs.args);
            help->docs.params = makeHint(NULL, 0, 0, help->docs);
        } else if (!strcmp(key, "subcommands")) {
            redisReply *subcommands = specs->element[j + 1];
            assert(subcommands->type == REDIS_REPLY_MAP || subcommands->type == REDIS_REPLY_ARRAY);
            for (size_t i = 0; i < subcommands->elements; i += 2) {
                assert(subcommands->element[i]->type == REDIS_REPLY_STRING);
                char *subcommandname = subcommands->element[i]->str;
                redisReply *subcommand = subcommands->element[i + 1];
                assert(subcommand->type == REDIS_REPLY_MAP || subcommand->type == REDIS_REPLY_ARRAY);
                next = cliInitCommandHelpEntry(cmdname, subcommandname, next, subcommand, groups);
            }
        }
    }
    return next;
}

/* Returns the total number of commands and subcommands in the command docs table. */
static size_t cliCountCommands(redisReply *commandTable) {
    size_t numCommands = commandTable->elements / 2;

    /* The command docs table maps command names to a map of their specs. */
    for (size_t i = 0; i < commandTable->elements; i += 2) {
        assert(commandTable->element[i]->type == REDIS_REPLY_STRING); /* Command name. */
        assert(commandTable->element[i + 1]->type == REDIS_REPLY_MAP ||
               commandTable->element[i + 1]->type == REDIS_REPLY_ARRAY);
        redisReply *map = commandTable->element[i + 1];
        for (size_t j = 0; j < map->elements; j += 2) {
            assert(map->element[j]->type == REDIS_REPLY_STRING);
            char *key = map->element[j]->str;
            if (!strcmp(key, "subcommands")) {
                redisReply *subcommands = map->element[j + 1];
                assert(subcommands->type == REDIS_REPLY_MAP || subcommands->type == REDIS_REPLY_ARRAY);
                numCommands += subcommands->elements / 2;
            }
        }
    }
    return numCommands;
}

/* Comparator for sorting help table entries. */
int helpEntryCompare(const void *entry1, const void *entry2) {
    helpEntry *i1 = (helpEntry *)entry1;
    helpEntry *i2 = (helpEntry *)entry2;
    return strcmp(i1->full, i2->full);
}

/* Initializes command help entries for command groups.
 * Called after the command help entries have already been filled in.
 * Extends the help table with new entries for the command groups.
 */
void cliInitGroupHelpEntries(dict *groups) {
    dictIterator *iter = dictGetIterator(groups);
    dictEntry *entry;
    helpEntry tmp;

    int numGroups = dictSize(groups);
    int pos = helpEntriesLen;
    helpEntriesLen += numGroups;
    helpEntries = zrealloc(helpEntries, sizeof(helpEntry) * helpEntriesLen);

    for (entry = dictNext(iter); entry != NULL; entry = dictNext(iter)) {
        tmp.argc = 1;
        tmp.argv = zmalloc(sizeof(sds));
        tmp.argv[0] = sdscatprintf(sdsempty(), "@%s", (char *)dictGetKey(entry));
        tmp.full = tmp.argv[0];
        tmp.type = CLI_HELP_GROUP;
        tmp.docs.name = NULL;
        tmp.docs.params = NULL;
        tmp.docs.args = NULL;
        tmp.docs.numargs = 0;
        tmp.docs.summary = NULL;
        tmp.docs.since = NULL;
        tmp.docs.group = NULL;
        helpEntries[pos++] = tmp;
    }
    dictReleaseIterator(iter);
}

/* Initializes help entries for all commands in the COMMAND DOCS reply. */
void cliInitCommandHelpEntries(redisReply *commandTable, dict *groups) {
    helpEntry *next = helpEntries;
    for (size_t i = 0; i < commandTable->elements; i += 2) {
        assert(commandTable->element[i]->type == REDIS_REPLY_STRING);
        char *cmdname = commandTable->element[i]->str;

        assert(commandTable->element[i + 1]->type == REDIS_REPLY_MAP ||
               commandTable->element[i + 1]->type == REDIS_REPLY_ARRAY);
        redisReply *cmdspecs = commandTable->element[i + 1];
        next = cliInitCommandHelpEntry(cmdname, NULL, next, cmdspecs, groups);
    }
}

/* Does the server version support a command/argument only available "since" some version?
 * Returns 1 when supported, or 0 when the "since" version is newer than "version". */
static int versionIsSupported(sds version, sds since) {
    int i;
    char *versionPos = version;
    char *sincePos = since;
    if (!since) {
        return 1;
    }

    for (i = 0; i != 3; i++) {
        int versionPart = atoi(versionPos);
        int sincePart = atoi(sincePos);
        if (versionPart > sincePart) {
            return 1;
        } else if (sincePart > versionPart) {
            return 0;
        }
        versionPos = strchr(versionPos, '.');
        sincePos = strchr(sincePos, '.');

        /* If we finished to parse both `version` and `since`, it means they are equal */
        if (!versionPos && !sincePos) return 1;

        /* Different number of digits considered as not supported */
        if (!versionPos || !sincePos) return 0;

        versionPos++;
        sincePos++;
    }
    return 0;
}

static void removeUnsupportedArgs(struct cliCommandArg *args, int *numargs, sds version) {
    int i = 0, j;
    while (i != *numargs) {
        if (versionIsSupported(version, args[i].since)) {
            if (args[i].subargs) {
                removeUnsupportedArgs(args[i].subargs, &args[i].numsubargs, version);
            }
            i++;
            continue;
        }
        for (j = i; j != *numargs - 1; j++) {
            args[j] = args[j + 1];
        }
        (*numargs)--;
    }
}

static helpEntry *cliLegacyInitCommandHelpEntry(char *cmdname,
                                                char *subcommandname,
                                                helpEntry *next,
                                                struct commandDocs *command,
                                                dict *groups,
                                                sds version) {
    helpEntry *help = next++;
    cliFillInCommandHelpEntry(help, cmdname, subcommandname);

    help->docs.summary = sdsnew(command->summary);
    help->docs.since = sdsnew(command->since);
    help->docs.group = sdsnew(command->group);
    sds group = sdsdup(help->docs.group);
    if (dictAdd(groups, group, NULL) != DICT_OK) {
        sdsfree(group);
    }

    if (command->args != NULL) {
        help->docs.args = command->args;
        help->docs.numargs = command->numargs;
        if (version) removeUnsupportedArgs(help->docs.args, &help->docs.numargs, version);
        help->docs.params = makeHint(NULL, 0, 0, help->docs);
    }

    if (command->subcommands != NULL) {
        for (size_t i = 0; command->subcommands[i].name != NULL; i++) {
            if (!version || versionIsSupported(version, command->subcommands[i].since)) {
                char *subcommandname = command->subcommands[i].name;
                next = cliLegacyInitCommandHelpEntry(cmdname, subcommandname, next, &command->subcommands[i], groups,
                                                     version);
            }
        }
    }
    return next;
}

int cliLegacyInitCommandHelpEntries(struct commandDocs *commands, dict *groups, sds version) {
    helpEntry *next = helpEntries;
    for (size_t i = 0; commands[i].name != NULL; i++) {
        if (!version || versionIsSupported(version, commands[i].since)) {
            next = cliLegacyInitCommandHelpEntry(commands[i].name, NULL, next, &commands[i], groups, version);
        }
    }
    return next - helpEntries;
}

/* Returns the total number of commands and subcommands in the command docs table,
 * filtered by server version (if provided).
 */
static size_t cliLegacyCountCommands(struct commandDocs *commands, sds version) {
    int numCommands = 0;
    for (size_t i = 0; commands[i].name != NULL; i++) {
        if (version && !versionIsSupported(version, commands[i].since)) {
            continue;
        }
        numCommands++;
        if (commands[i].subcommands != NULL) {
            numCommands += cliLegacyCountCommands(commands[i].subcommands, version);
        }
    }
    return numCommands;
}

/* Gets the server version string by calling INFO SERVER.
 * Stores the result in config.server_version.
 * When not connected, or not possible, returns NULL. */
static sds cliGetServerVersion(void) {
    static const char *key = "\nvalkey_version:";
    redisReply *serverInfo = NULL;
    char *pos;

    if (config.server_version != NULL) {
        return config.server_version;
    }

    if (!context) return NULL;
    serverInfo = redisCommand(context, "INFO SERVER");
    if (serverInfo == NULL || serverInfo->type == REDIS_REPLY_ERROR) {
        freeReplyObject(serverInfo);
        return sdsempty();
    }

    assert(serverInfo->type == REDIS_REPLY_STRING || serverInfo->type == REDIS_REPLY_VERB);
    sds info = serverInfo->str;

    /* Finds the first appearance of "valkey_version" in the INFO SERVER reply. */
    pos = strstr(info, key);
    if (pos) {
        pos += strlen(key);
        char *end = strchr(pos, '\r');
        if (end) {
            sds version = sdsnewlen(pos, end - pos);
            freeReplyObject(serverInfo);
            config.server_version = version;
            return version;
        }
    }
    freeReplyObject(serverInfo);
    return NULL;
}

static void cliLegacyInitHelp(dict *groups) {
    sds serverVersion = cliGetServerVersion();

    /* Scan the commandDocs array and fill in the entries */
    helpEntriesLen = cliLegacyCountCommands(serverCommandTable, serverVersion);
    helpEntries = zmalloc(sizeof(helpEntry) * helpEntriesLen);

    helpEntriesLen = cliLegacyInitCommandHelpEntries(serverCommandTable, groups, serverVersion);
    cliInitGroupHelpEntries(groups);

    qsort(helpEntries, helpEntriesLen, sizeof(helpEntry), helpEntryCompare);
    dictRelease(groups);
}

/* cliInitHelp() sets up the helpEntries array with the command and group
 * names and command descriptions obtained using the COMMAND DOCS command.
 */
static void cliInitHelp(void) {
    /* Dict type for a set of strings, used to collect names of command groups. */
    dictType groupsdt = {
        dictSdsHash,       /* hash function */
        NULL,              /* key dup */
        dictSdsKeyCompare, /* key compare */
        dictSdsDestructor, /* key destructor */
        NULL,              /* val destructor */
        NULL               /* allow to expand */
    };
    redisReply *commandTable;
    dict *groups;

    if (cliConnect(CC_QUIET) == REDIS_ERR) {
        /* Can not connect to the server, but we still want to provide
         * help, generate it only from the static cli_commands.c data instead. */
        groups = dictCreate(&groupsdt);
        cliLegacyInitHelp(groups);
        return;
    }
    commandTable = redisCommand(context, "COMMAND DOCS");
    if (commandTable == NULL || commandTable->type == REDIS_REPLY_ERROR) {
        /* New COMMAND DOCS subcommand not supported - generate help from
         * static cli_commands.c data instead. */
        freeReplyObject(commandTable);

        groups = dictCreate(&groupsdt);
        cliLegacyInitHelp(groups);
        cliLegacyIntegrateHelp();
        return;
    };
    if (commandTable->type != REDIS_REPLY_MAP && commandTable->type != REDIS_REPLY_ARRAY) return;

    /* Scan the array reported by COMMAND DOCS and fill in the entries */
    helpEntriesLen = cliCountCommands(commandTable);
    helpEntries = zmalloc(sizeof(helpEntry) * helpEntriesLen);

    groups = dictCreate(&groupsdt);
    cliInitCommandHelpEntries(commandTable, groups);
    cliInitGroupHelpEntries(groups);

    qsort(helpEntries, helpEntriesLen, sizeof(helpEntry), helpEntryCompare);
    freeReplyObject(commandTable);
    dictRelease(groups);
}

/* Output command help to stdout. */
static void cliOutputCommandHelp(struct commandDocs *help, int group) {
    printf("\r\n  \x1b[1m%s\x1b[0m \x1b[90m%s\x1b[0m\r\n", help->name, help->params);
    printf("  \x1b[33msummary:\x1b[0m %s\r\n", help->summary);
    if (help->since != NULL) {
        printf("  \x1b[33msince:\x1b[0m %s\r\n", help->since);
    }
    if (group) {
        printf("  \x1b[33mgroup:\x1b[0m %s\r\n", help->group);
    }
}

/* Print generic help. */
static void cliOutputGenericHelp(void) {
    sds version = cliVersion();
    printf("valkey-cli %s\n"
           "To get help about Valkey commands type:\n"
           "      \"help @<group>\" to get a list of commands in <group>\n"
           "      \"help <command>\" for help on <command>\n"
           "      \"help <tab>\" to get a list of possible help topics\n"
           "      \"quit\" to exit\n"
           "\n"
           "To set valkey-cli preferences:\n"
           "      \":set hints\" enable online hints\n"
           "      \":set nohints\" disable online hints\n"
           "Set your preferences in ~/.valkeyclirc\n",
           version);
    sdsfree(version);
}

/* Output all command help, filtering by group or command name. */
static void cliOutputHelp(int argc, char **argv) {
    int i, j;
    char *group = NULL;
    helpEntry *entry;
    struct commandDocs *help;

    if (argc == 0) {
        cliOutputGenericHelp();
        return;
    } else if (argc > 0 && argv[0][0] == '@') {
        group = argv[0] + 1;
    }

    if (helpEntries == NULL) {
        /* Initialize the help using the results of the COMMAND command.
         * In case we are using valkey-cli help XXX, we need to init it. */
        cliInitHelp();
    }

    assert(argc > 0);
    for (i = 0; i < helpEntriesLen; i++) {
        entry = &helpEntries[i];
        if (entry->type != CLI_HELP_COMMAND) continue;

        help = &entry->docs;
        if (group == NULL) {
            /* Compare all arguments */
            if (argc <= entry->argc) {
                for (j = 0; j < argc; j++) {
                    if (strcasecmp(argv[j], entry->argv[j]) != 0) break;
                }
                if (j == argc) {
                    cliOutputCommandHelp(help, 1);
                }
            }
        } else if (strcasecmp(group, help->group) == 0) {
            cliOutputCommandHelp(help, 0);
        }
    }
    printf("\r\n");
}

/* Linenoise completion callback. */
static void completionCallback(const char *buf, linenoiseCompletions *lc) {
    size_t startpos = 0;
    int mask;
    int i;
    size_t matchlen;
    sds tmp;

    if (strncasecmp(buf, "help ", 5) == 0) {
        startpos = 5;
        while (isspace(buf[startpos])) startpos++;
        mask = CLI_HELP_COMMAND | CLI_HELP_GROUP;
    } else {
        mask = CLI_HELP_COMMAND;
    }

    for (i = 0; i < helpEntriesLen; i++) {
        if (!(helpEntries[i].type & mask)) continue;

        matchlen = strlen(buf + startpos);
        if (strncasecmp(buf + startpos, helpEntries[i].full, matchlen) == 0) {
            tmp = sdsnewlen(buf, startpos);
            tmp = sdscat(tmp, helpEntries[i].full);
            linenoiseAddCompletion(lc, tmp);
            sdsfree(tmp);
        }
    }
}

static sds addHintForArgument(sds hint, cliCommandArg *arg);

/* Adds a separator character between words of a string under construction.
 * A separator is added if the string length is greater than its previously-recorded
 * length (*len), which is then updated, and it's not the last word to be added.
 */
static sds addSeparator(sds str, size_t *len, char *separator, int is_last) {
    if (sdslen(str) > *len && !is_last) {
        str = sdscat(str, separator);
        *len = sdslen(str);
    }
    return str;
}

/* Recursively zeros the matched* fields of all arguments. */
static void clearMatchedArgs(cliCommandArg *args, int numargs) {
    for (int i = 0; i != numargs; ++i) {
        args[i].matched = 0;
        args[i].matched_token = 0;
        args[i].matched_name = 0;
        args[i].matched_all = 0;
        if (args[i].subargs) {
            clearMatchedArgs(args[i].subargs, args[i].numsubargs);
        }
    }
}

/* Builds a completion hint string describing the arguments, skipping parts already matched.
 * Hints for all arguments are added to the input 'hint' parameter, separated by 'separator'.
 */
static sds addHintForArguments(sds hint, cliCommandArg *args, int numargs, char *separator) {
    int i, j, incomplete;
    size_t len = sdslen(hint);
    for (i = 0; i < numargs; i++) {
        if (!(args[i].flags & CMD_ARG_OPTIONAL)) {
            hint = addHintForArgument(hint, &args[i]);
            hint = addSeparator(hint, &len, separator, i == numargs - 1);
            continue;
        }

        /* The rule is that successive "optional" arguments can appear in any order.
         * But if they are followed by a required argument, no more of those optional arguments
         * can appear after that.
         *
         * This code handles all successive optional args together. This lets us show the
         * completion of the currently-incomplete optional arg first, if there is one.
         */
        for (j = i, incomplete = -1; j < numargs; j++) {
            if (!(args[j].flags & CMD_ARG_OPTIONAL)) break;
            if (args[j].matched != 0 && args[j].matched_all == 0) {
                /* User has started typing this arg; show its completion first. */
                hint = addHintForArgument(hint, &args[j]);
                hint = addSeparator(hint, &len, separator, i == numargs - 1);
                incomplete = j;
            }
        }

        /* If the following non-optional arg has not been matched, add hints for
         * any remaining optional args in this group.
         */
        if (j == numargs || args[j].matched == 0) {
            for (; i < j; i++) {
                if (incomplete != i) {
                    hint = addHintForArgument(hint, &args[i]);
                    hint = addSeparator(hint, &len, separator, i == numargs - 1);
                }
            }
        }

        i = j - 1;
    }
    return hint;
}

/* Adds the "repeating" section of the hint string for a multiple-typed argument: [ABC def ...]
 * The repeating part is a fixed unit; we don't filter matched elements from it.
 */
static sds addHintForRepeatedArgument(sds hint, cliCommandArg *arg) {
    if (!(arg->flags & CMD_ARG_MULTIPLE)) {
        return hint;
    }

    /* The repeating part is always shown at the end of the argument's hint,
     * so we can safely clear its matched flags before printing it.
     */
    clearMatchedArgs(arg, 1);

    if (hint[0] != '\0') {
        hint = sdscat(hint, " ");
    }
    hint = sdscat(hint, "[");

    if (arg->flags & CMD_ARG_MULTIPLE_TOKEN) {
        hint = sdscat_orempty(hint, arg->token);
        if (arg->type != ARG_TYPE_PURE_TOKEN) {
            hint = sdscat(hint, " ");
        }
    }

    switch (arg->type) {
    case ARG_TYPE_ONEOF: hint = addHintForArguments(hint, arg->subargs, arg->numsubargs, "|"); break;

    case ARG_TYPE_BLOCK: hint = addHintForArguments(hint, arg->subargs, arg->numsubargs, " "); break;

    case ARG_TYPE_PURE_TOKEN: break;

    default: hint = sdscat_orempty(hint, arg->display_text ? arg->display_text : arg->name); break;
    }

    hint = sdscat(hint, " ...]");
    return hint;
}

/* Adds hint string for one argument, if not already matched. */
static sds addHintForArgument(sds hint, cliCommandArg *arg) {
    if (arg->matched_all) {
        return hint;
    }

    /* Surround an optional arg with brackets, unless it's partially matched. */
    if ((arg->flags & CMD_ARG_OPTIONAL) && !arg->matched) {
        hint = sdscat(hint, "[");
    }

    /* Start with the token, if present and not matched. */
    if (arg->token != NULL && !arg->matched_token) {
        hint = sdscat_orempty(hint, arg->token);
        if (arg->type != ARG_TYPE_PURE_TOKEN) {
            hint = sdscat(hint, " ");
        }
    }

    /* Add the body of the syntax string. */
    switch (arg->type) {
    case ARG_TYPE_ONEOF:
        if (arg->matched == 0) {
            hint = addHintForArguments(hint, arg->subargs, arg->numsubargs, "|");
        } else {
            int i;
            for (i = 0; i < arg->numsubargs; i++) {
                if (arg->subargs[i].matched != 0) {
                    hint = addHintForArgument(hint, &arg->subargs[i]);
                }
            }
        }
        break;

    case ARG_TYPE_BLOCK: hint = addHintForArguments(hint, arg->subargs, arg->numsubargs, " "); break;

    case ARG_TYPE_PURE_TOKEN: break;

    default:
        if (!arg->matched_name) {
            hint = sdscat_orempty(hint, arg->display_text ? arg->display_text : arg->name);
        }
        break;
    }

    hint = addHintForRepeatedArgument(hint, arg);

    if ((arg->flags & CMD_ARG_OPTIONAL) && !arg->matched) {
        hint = sdscat(hint, "]");
    }

    return hint;
}

static int matchArg(char **nextword, int numwords, cliCommandArg *arg);
static int matchArgs(char **words, int numwords, cliCommandArg *args, int numargs);

/* Tries to match the next words of the input against an argument. */
static int matchNoTokenArg(char **nextword, int numwords, cliCommandArg *arg) {
    int i;
    switch (arg->type) {
    case ARG_TYPE_BLOCK: {
        arg->matched += matchArgs(nextword, numwords, arg->subargs, arg->numsubargs);

        /* All the subargs must be matched for the block to match. */
        arg->matched_all = 1;
        for (i = 0; i < arg->numsubargs; i++) {
            if (arg->subargs[i].matched_all == 0) {
                arg->matched_all = 0;
            }
        }
        break;
    }
    case ARG_TYPE_ONEOF: {
        for (i = 0; i < arg->numsubargs; i++) {
            if (matchArg(nextword, numwords, &arg->subargs[i])) {
                arg->matched += arg->subargs[i].matched;
                arg->matched_all = arg->subargs[i].matched_all;
                break;
            }
        }
        break;
    }

    case ARG_TYPE_INTEGER:
    case ARG_TYPE_UNIX_TIME: {
        long long value;
        if (sscanf(*nextword, "%lld", &value) == 1) {
            arg->matched += 1;
            arg->matched_name = 1;
            arg->matched_all = 1;
        } else {
            /* Matching failed due to incorrect arg type. */
            arg->matched = 0;
            arg->matched_name = 0;
        }
        break;
    }

    case ARG_TYPE_DOUBLE: {
        double value;
        if (sscanf(*nextword, "%lf", &value) == 1) {
            arg->matched += 1;
            arg->matched_name = 1;
            arg->matched_all = 1;
        } else {
            /* Matching failed due to incorrect arg type. */
            arg->matched = 0;
            arg->matched_name = 0;
        }
        break;
    }

    default:
        arg->matched += 1;
        arg->matched_name = 1;
        arg->matched_all = 1;
        break;
    }
    return arg->matched;
}

/* Tries to match the next word of the input against a token literal. */
static int matchToken(char **nextword, cliCommandArg *arg) {
    if (strcasecmp(arg->token, nextword[0]) != 0) {
        return 0;
    }
    arg->matched_token = 1;
    arg->matched = 1;
    return 1;
}

/* Tries to match the next words of the input against the next argument.
 * If the arg is repeated ("multiple"), it will be matched only once.
 * If the next input word(s) can't be matched, returns 0 for failure.
 */
static int matchArgOnce(char **nextword, int numwords, cliCommandArg *arg) {
    /* First match the token, if present. */
    if (arg->token != NULL) {
        if (!matchToken(nextword, arg)) {
            return 0;
        }
        if (arg->type == ARG_TYPE_PURE_TOKEN) {
            arg->matched_all = 1;
            return 1;
        }
        if (numwords == 1) {
            return 1;
        }
        nextword++;
        numwords--;
    }

    /* Then match the rest of the argument. */
    if (!matchNoTokenArg(nextword, numwords, arg)) {
        return 0;
    }
    return arg->matched;
}

/* Tries to match the next words of the input against the next argument.
 * If the arg is repeated ("multiple"), it will be matched as many times as possible.
 */
static int matchArg(char **nextword, int numwords, cliCommandArg *arg) {
    int matchedWords = 0;
    int matchedOnce = matchArgOnce(nextword, numwords, arg);
    if (!(arg->flags & CMD_ARG_MULTIPLE)) {
        return matchedOnce;
    }

    /* Found one match; now match a "multiple" argument as many times as possible. */
    matchedWords += matchedOnce;
    while (arg->matched_all && matchedWords < numwords) {
        clearMatchedArgs(arg, 1);
        if (arg->token != NULL && !(arg->flags & CMD_ARG_MULTIPLE_TOKEN)) {
            /* The token only appears the first time; the rest of the times,
             * pretend we saw it so we don't hint it.
             */
            matchedOnce = matchNoTokenArg(nextword + matchedWords, numwords - matchedWords, arg);
            if (arg->matched) {
                arg->matched_token = 1;
            }
        } else {
            matchedOnce = matchArgOnce(nextword + matchedWords, numwords - matchedWords, arg);
        }
        matchedWords += matchedOnce;
    }
    arg->matched_all = 0; /* Because more repetitions are still possible. */
    return matchedWords;
}

/* Tries to match the next words of the input against
 * any one of a consecutive set of optional arguments.
 */
static int matchOneOptionalArg(char **words, int numwords, cliCommandArg *args, int numargs, int *matchedarg) {
    for (int nextword = 0, nextarg = 0; nextword != numwords && nextarg != numargs; ++nextarg) {
        if (args[nextarg].matched) {
            /* Already matched this arg. */
            continue;
        }

        int matchedWords = matchArg(&words[nextword], numwords - nextword, &args[nextarg]);
        if (matchedWords != 0) {
            *matchedarg = nextarg;
            return matchedWords;
        }
    }
    return 0;
}

/* Matches as many input words as possible against a set of consecutive optional arguments. */
static int matchOptionalArgs(char **words, int numwords, cliCommandArg *args, int numargs) {
    int nextword = 0;
    int matchedarg = -1, lastmatchedarg = -1;
    while (nextword != numwords) {
        int matchedWords = matchOneOptionalArg(&words[nextword], numwords - nextword, args, numargs, &matchedarg);
        if (matchedWords == 0) {
            break;
        }
        /* Successfully matched an optional arg; mark any previous match as completed
         * so it won't be partially hinted.
         */
        if (lastmatchedarg != -1) {
            args[lastmatchedarg].matched_all = 1;
        }
        lastmatchedarg = matchedarg;
        nextword += matchedWords;
    }
    return nextword;
}

/* Matches as many input words as possible against command arguments. */
static int matchArgs(char **words, int numwords, cliCommandArg *args, int numargs) {
    int nextword, nextarg, matchedWords;
    for (nextword = 0, nextarg = 0; nextword != numwords && nextarg != numargs; ++nextarg) {
        /* Optional args can occur in any order. Collect a range of consecutive optional args
         * and try to match them as a group against the next input words.
         */
        if (args[nextarg].flags & CMD_ARG_OPTIONAL) {
            int lastoptional;
            for (lastoptional = nextarg; lastoptional < numargs; lastoptional++) {
                if (!(args[lastoptional].flags & CMD_ARG_OPTIONAL)) break;
            }
            matchedWords =
                matchOptionalArgs(&words[nextword], numwords - nextword, &args[nextarg], lastoptional - nextarg);
            nextarg = lastoptional - 1;
        } else {
            matchedWords = matchArg(&words[nextword], numwords - nextword, &args[nextarg]);
            if (matchedWords == 0) {
                /* Couldn't match a required word - matching fails! */
                return 0;
            }
        }

        nextword += matchedWords;
    }
    return nextword;
}

/* Compute the linenoise hint for the input prefix in inputargv/inputargc.
 * cmdlen is the number of words from the start of the input that make up the command.
 * If docs.args exists, dynamically creates a hint string by matching the arg specs
 * against the input words.
 */
static sds makeHint(char **inputargv, int inputargc, int cmdlen, struct commandDocs docs) {
    sds hint;

    if (docs.args) {
        /* Remove arguments from the returned hint to show only the
         * ones the user did not yet type. */
        clearMatchedArgs(docs.args, docs.numargs);
        hint = sdsempty();
        int matchedWords = 0;
        if (inputargv && inputargc)
            matchedWords = matchArgs(inputargv + cmdlen, inputargc - cmdlen, docs.args, docs.numargs);
        if (matchedWords == inputargc - cmdlen) {
            hint = addHintForArguments(hint, docs.args, docs.numargs, " ");
        }
        return hint;
    }

    /* If arg specs are not available, show the hint string until the user types something. */
    if (inputargc <= cmdlen) {
        hint = sdsnew(docs.params);
    } else {
        hint = sdsempty();
    }
    return hint;
}

/* Search for a command matching the longest possible prefix of input words. */
static helpEntry *findHelpEntry(int argc, char **argv) {
    helpEntry *entry = NULL;
    int i, rawargc, matchlen = 0;
    sds *rawargv;

    for (i = 0; i < helpEntriesLen; i++) {
        if (!(helpEntries[i].type & CLI_HELP_COMMAND)) continue;

        rawargv = helpEntries[i].argv;
        rawargc = helpEntries[i].argc;
        if (rawargc <= argc) {
            int j;
            for (j = 0; j < rawargc; j++) {
                if (strcasecmp(rawargv[j], argv[j])) {
                    break;
                }
            }
            if (j == rawargc && rawargc > matchlen) {
                matchlen = rawargc;
                entry = &helpEntries[i];
            }
        }
    }
    return entry;
}

/* Returns the command-line hint string for a given partial input. */
static sds getHintForInput(const char *charinput) {
    sds hint = NULL;
    int inputargc, inputlen = strlen(charinput);
    sds *inputargv = sdssplitargs(charinput, &inputargc);
    int endspace = inputlen && isspace(charinput[inputlen - 1]);

    /* Don't match the last word until the user has typed a space after it. */
    int matchargc = endspace ? inputargc : inputargc - 1;

    helpEntry *entry = findHelpEntry(matchargc, inputargv);
    if (entry) {
        hint = makeHint(inputargv, matchargc, entry->argc, entry->docs);
    }
    sdsfreesplitres(inputargv, inputargc);
    return hint;
}

/* Linenoise hints callback. */
static char *hintsCallback(const char *buf, int *color, int *bold) {
    if (!pref.hints) return NULL;

    sds hint = getHintForInput(buf);
    if (hint == NULL) {
        return NULL;
    }

    *color = 90;
    *bold = 0;

    /* Add an initial space if needed. */
    int len = strlen(buf);
    int endspace = len && isspace(buf[len - 1]);
    if (!endspace) {
        sds newhint = sdsnewlen(" ", 1);
        newhint = sdscatsds(newhint, hint);
        sdsfree(hint);
        hint = newhint;
    }

    return hint;
}

static void freeHintsCallback(void *ptr) {
    sdsfree(ptr);
}

/*------------------------------------------------------------------------------
 * TTY manipulation
 *--------------------------------------------------------------------------- */

/* Restore terminal if we've changed it. */
void cliRestoreTTY(void) {
    if (orig_termios_saved) tcsetattr(STDIN_FILENO, TCSANOW, &orig_termios);
}

/* Put the terminal in "press any key" mode */
static void cliPressAnyKeyTTY(void) {
    if (!isatty(STDIN_FILENO)) return;
    if (!orig_termios_saved) {
        if (tcgetattr(STDIN_FILENO, &orig_termios) == -1) return;
        atexit(cliRestoreTTY);
        orig_termios_saved = 1;
    }
    struct termios mode = orig_termios;
    mode.c_lflag &= ~(ECHO | ICANON); /* echoing off, canonical off */
    tcsetattr(STDIN_FILENO, TCSANOW, &mode);
}

/*------------------------------------------------------------------------------
 * Networking / parsing
 *--------------------------------------------------------------------------- */

/* Send AUTH command to the server */
static int cliAuth(redisContext *ctx, char *user, char *auth) {
    redisReply *reply;
    if (auth == NULL) return REDIS_OK;

    if (user == NULL)
        reply = redisCommand(ctx, "AUTH %s", auth);
    else
        reply = redisCommand(ctx, "AUTH %s %s", user, auth);

    if (reply == NULL) {
        fprintf(stderr, "\nI/O error\n");
        return REDIS_ERR;
    }

    int result = REDIS_OK;
    if (reply->type == REDIS_REPLY_ERROR) {
        result = REDIS_ERR;
        fprintf(stderr, "AUTH failed: %s\n", reply->str);
    }
    freeReplyObject(reply);
    return result;
}

/* Send SELECT input_dbnum to the server */
static int cliSelect(void) {
    redisReply *reply;
    if (config.conn_info.input_dbnum == config.dbnum) return REDIS_OK;

    reply = redisCommand(context, "SELECT %d", config.conn_info.input_dbnum);
    if (reply == NULL) {
        fprintf(stderr, "\nI/O error\n");
        return REDIS_ERR;
    }

    int result = REDIS_OK;
    if (reply->type == REDIS_REPLY_ERROR) {
        result = REDIS_ERR;
        fprintf(stderr, "SELECT %d failed: %s\n", config.conn_info.input_dbnum, reply->str);
    } else {
        config.dbnum = config.conn_info.input_dbnum;
        cliRefreshPrompt();
    }
    freeReplyObject(reply);
    return result;
}

/* Select RESP3 mode if valkey-cli was started with the -3 option.  */
static int cliSwitchProto(void) {
    redisReply *reply;
    if (!config.resp3 || config.resp2) return REDIS_OK;

    reply = redisCommand(context, "HELLO 3");
    if (reply == NULL) {
        fprintf(stderr, "\nI/O error\n");
        return REDIS_ERR;
    }

    int result = REDIS_OK;
    if (reply->type == REDIS_REPLY_ERROR) {
        fprintf(stderr, "HELLO 3 failed: %s\n", reply->str);
        if (config.resp3 == 1) {
            result = REDIS_ERR;
        } else if (config.resp3 == 2) {
            result = REDIS_OK;
        }
    }

    /* Retrieve server version string for later use. */
    for (size_t i = 0; i < reply->elements; i += 2) {
        assert(reply->element[i]->type == REDIS_REPLY_STRING);
        char *key = reply->element[i]->str;
        if (!strcmp(key, "version")) {
            assert(reply->element[i + 1]->type == REDIS_REPLY_STRING);
            config.server_version = sdsnew(reply->element[i + 1]->str);
        }
    }
    freeReplyObject(reply);
    config.current_resp3 = 1;
    return result;
}

/* Connect to the server. It is possible to pass certain flags to the function:
 *      CC_FORCE: The connection is performed even if there is already
 *                a connected socket.
 *      CC_QUIET: Don't print errors if connection fails. */
static int cliConnect(int flags) {
    if (context == NULL || flags & CC_FORCE) {
        if (context != NULL) {
            redisFree(context);
            config.dbnum = 0;
            config.in_multi = 0;
            config.pubsub_mode = 0;
            cliRefreshPrompt();
        }

        /* Do not use hostsocket when we got redirected in cluster mode */
        if (config.hostsocket == NULL || (config.cluster_mode && config.cluster_reissue_command)) {
            context = redisConnectWrapper(config.conn_info.hostip, config.conn_info.hostport, config.connect_timeout);
        } else {
            context = redisConnectUnixWrapper(config.hostsocket, config.connect_timeout);
        }

        if (!context->err && config.tls) {
            const char *err = NULL;
            if (cliSecureConnection(context, config.sslconfig, &err) == REDIS_ERR && err) {
                fprintf(stderr, "Could not negotiate a TLS connection: %s\n", err);
                redisFree(context);
                context = NULL;
                return REDIS_ERR;
            }
        }

        if (context->err) {
            if (!(flags & CC_QUIET)) {
                fprintf(stderr, "Could not connect to Valkey at ");
                if (config.hostsocket == NULL || (config.cluster_mode && config.cluster_reissue_command)) {
                    fprintf(stderr, "%s:%d: %s\n", config.conn_info.hostip, config.conn_info.hostport, context->errstr);
                } else {
                    fprintf(stderr, "%s: %s\n", config.hostsocket, context->errstr);
                }
            }
            redisFree(context);
            context = NULL;
            return REDIS_ERR;
        }


        /* Set aggressive KEEP_ALIVE socket option in the server context socket
         * in order to prevent timeouts caused by the execution of long
         * commands. At the same time this improves the detection of real
         * errors. */
        anetKeepAlive(NULL, context->fd, CLI_KEEPALIVE_INTERVAL);

        /* State of the current connection. */
        config.current_resp3 = 0;

        /* Do AUTH, select the right DB, switch to RESP3 if needed. */
        if (cliAuth(context, config.conn_info.user, config.conn_info.auth) != REDIS_OK) return REDIS_ERR;
        if (cliSelect() != REDIS_OK) return REDIS_ERR;
        if (cliSwitchProto() != REDIS_OK) return REDIS_ERR;
    }

    /* Set a PUSH handler if configured to do so. */
    if (config.push_output) {
        redisSetPushCallback(context, cliPushHandler);
    }

    return REDIS_OK;
}

/* In cluster, if server replies ASK, we will redirect to a different node.
 * Before sending the real command, we need to send ASKING command first. */
static int cliSendAsking(void) {
    redisReply *reply;

    config.cluster_send_asking = 0;
    if (context == NULL) {
        return REDIS_ERR;
    }
    reply = redisCommand(context, "ASKING");
    if (reply == NULL) {
        fprintf(stderr, "\nI/O error\n");
        return REDIS_ERR;
    }
    int result = REDIS_OK;
    if (reply->type == REDIS_REPLY_ERROR) {
        result = REDIS_ERR;
        fprintf(stderr, "ASKING failed: %s\n", reply->str);
    }
    freeReplyObject(reply);
    return result;
}

static void cliPrintContextError(void) {
    if (context == NULL) return;
    fprintf(stderr, "Error: %s\n", context->errstr);
}

static int isInvalidateReply(redisReply *reply) {
    return reply->type == REDIS_REPLY_PUSH && reply->elements == 2 && reply->element[0]->type == REDIS_REPLY_STRING &&
           !strncmp(reply->element[0]->str, "invalidate", 10) && reply->element[1]->type == REDIS_REPLY_ARRAY;
}

/* Special display handler for RESP3 'invalidate' messages.
 * This function does not validate the reply, so it should
 * already be confirmed correct */
static sds cliFormatInvalidateTTY(redisReply *r) {
    sds out = sdsnew("-> invalidate: ");

    for (size_t i = 0; i < r->element[1]->elements; i++) {
        redisReply *key = r->element[1]->element[i];
        assert(key->type == REDIS_REPLY_STRING);

        out = sdscatfmt(out, "'%s'", key->str, key->len);
        if (i < r->element[1]->elements - 1) out = sdscatlen(out, ", ", 2);
    }

    return sdscatlen(out, "\n", 1);
}

/* Returns non-zero if cliFormatReplyTTY renders the reply in multiple lines. */
static int cliIsMultilineValueTTY(redisReply *r) {
    switch (r->type) {
    case REDIS_REPLY_ARRAY:
    case REDIS_REPLY_SET:
    case REDIS_REPLY_PUSH:
        if (r->elements == 0) return 0;
        if (r->elements > 1) return 1;
        return cliIsMultilineValueTTY(r->element[0]);
    case REDIS_REPLY_MAP:
        if (r->elements == 0) return 0;
        if (r->elements > 2) return 1;
        return cliIsMultilineValueTTY(r->element[1]);
    default: return 0;
    }
}

static sds cliFormatReplyTTY(redisReply *r, char *prefix) {
    sds out = sdsempty();
    switch (r->type) {
    case REDIS_REPLY_ERROR: out = sdscatprintf(out, "(error) %s\n", r->str); break;
    case REDIS_REPLY_STATUS:
        out = sdscat(out, r->str);
        out = sdscat(out, "\n");
        break;
    case REDIS_REPLY_INTEGER: out = sdscatprintf(out, "(integer) %lld\n", r->integer); break;
    case REDIS_REPLY_DOUBLE: out = sdscatprintf(out, "(double) %s\n", r->str); break;
    case REDIS_REPLY_STRING:
    case REDIS_REPLY_VERB:
        /* If you are producing output for the standard output we want
         * a more interesting output with quoted characters and so forth,
         * unless it's a verbatim string type. */
        if (r->type == REDIS_REPLY_STRING) {
            out = sdscatrepr(out, r->str, r->len);
            out = sdscat(out, "\n");
        } else {
            out = sdscatlen(out, r->str, r->len);
            out = sdscat(out, "\n");
        }
        break;
    case REDIS_REPLY_NIL: out = sdscat(out, "(nil)\n"); break;
    case REDIS_REPLY_BOOL: out = sdscat(out, r->integer ? "(true)\n" : "(false)\n"); break;
    case REDIS_REPLY_ARRAY:
    case REDIS_REPLY_MAP:
    case REDIS_REPLY_SET:
    case REDIS_REPLY_PUSH:
        if (r->elements == 0) {
            if (r->type == REDIS_REPLY_ARRAY)
                out = sdscat(out, "(empty array)\n");
            else if (r->type == REDIS_REPLY_MAP)
                out = sdscat(out, "(empty hash)\n");
            else if (r->type == REDIS_REPLY_SET)
                out = sdscat(out, "(empty set)\n");
            else if (r->type == REDIS_REPLY_PUSH)
                out = sdscat(out, "(empty push)\n");
            else
                out = sdscat(out, "(empty aggregate type)\n");
        } else {
            unsigned int i, idxlen = 0;
            char _prefixlen[16];
            char _prefixfmt[16];
            sds _prefix;
            sds tmp;

            /* Calculate chars needed to represent the largest index */
            i = r->elements;
            if (r->type == REDIS_REPLY_MAP) i /= 2;
            do {
                idxlen++;
                i /= 10;
            } while (i);

            /* Prefix for nested multi bulks should grow with idxlen+2 spaces */
            memset(_prefixlen, ' ', idxlen + 2);
            _prefixlen[idxlen + 2] = '\0';
            _prefix = sdscat(sdsnew(prefix), _prefixlen);

            /* Setup prefix format for every entry */
            char numsep;
            if (r->type == REDIS_REPLY_SET)
                numsep = '~';
            else if (r->type == REDIS_REPLY_MAP)
                numsep = '#';
            /* TODO: this would be a breaking change for scripts, do that in a major version. */
            /* else if (r->type == REDIS_REPLY_PUSH) numsep = '>'; */
            else
                numsep = ')';
            snprintf(_prefixfmt, sizeof(_prefixfmt), "%%s%%%ud%c ", idxlen, numsep);

            for (i = 0; i < r->elements; i++) {
                unsigned int human_idx = (r->type == REDIS_REPLY_MAP) ? i / 2 : i;
                human_idx++; /* Make it 1-based. */

                /* Don't use the prefix for the first element, as the parent
                 * caller already prepended the index number. */
                out = sdscatprintf(out, _prefixfmt, i == 0 ? "" : prefix, human_idx);

                /* Format the multi bulk entry */
                tmp = cliFormatReplyTTY(r->element[i], _prefix);
                out = sdscatlen(out, tmp, sdslen(tmp));
                sdsfree(tmp);

                /* For maps, format the value as well. */
                if (r->type == REDIS_REPLY_MAP) {
                    i++;
                    sdsrange(out, 0, -2);
                    out = sdscat(out, " => ");
                    if (cliIsMultilineValueTTY(r->element[i])) {
                        /* linebreak before multiline value to fix alignment */
                        out = sdscat(out, "\n");
                        out = sdscat(out, _prefix);
                    }
                    tmp = cliFormatReplyTTY(r->element[i], _prefix);
                    out = sdscatlen(out, tmp, sdslen(tmp));
                    sdsfree(tmp);
                }
            }
            sdsfree(_prefix);
        }
        break;
    default: fprintf(stderr, "Unknown reply type: %d\n", r->type); exit(1);
    }
    return out;
}

/* Returns 1 if the reply is a pubsub pushed reply. */
int isPubsubPush(redisReply *r) {
    if (r == NULL || r->type != (config.current_resp3 ? REDIS_REPLY_PUSH : REDIS_REPLY_ARRAY) || r->elements < 3 ||
        r->element[0]->type != REDIS_REPLY_STRING) {
        return 0;
    }
    char *str = r->element[0]->str;
    size_t len = r->element[0]->len;
    /* Check if it is [p|s][un]subscribe or [p|s]message, but even simpler, we
     * just check that it ends with "message" or "subscribe". */
    return ((len >= strlen("message") && !strcmp(str + len - strlen("message"), "message")) ||
            (len >= strlen("subscribe") && !strcmp(str + len - strlen("subscribe"), "subscribe")));
}

int isColorTerm(void) {
    char *t = getenv("TERM");
    return t != NULL && strstr(t, "xterm") != NULL;
}

/* Helper function for sdsCatColorizedLdbReply() appending colorize strings
 * to an SDS string. */
sds sdscatcolor(sds o, char *s, size_t len, char *color) {
    if (!isColorTerm()) return sdscatlen(o, s, len);

    int bold = strstr(color, "bold") != NULL;
    int ccode = 37; /* Defaults to white. */
    if (strstr(color, "red"))
        ccode = 31;
    else if (strstr(color, "green"))
        ccode = 32;
    else if (strstr(color, "yellow"))
        ccode = 33;
    else if (strstr(color, "blue"))
        ccode = 34;
    else if (strstr(color, "magenta"))
        ccode = 35;
    else if (strstr(color, "cyan"))
        ccode = 36;
    else if (strstr(color, "white"))
        ccode = 37;

    o = sdscatfmt(o, "\033[%i;%i;49m", bold, ccode);
    o = sdscatlen(o, s, len);
    o = sdscat(o, "\033[0m");
    return o;
}

/* Colorize Lua debugger status replies according to the prefix they
 * have. */
sds sdsCatColorizedLdbReply(sds o, char *s, size_t len) {
    char *color = "white";

    if (strstr(s, "<debug>")) color = "bold";
    if (strstr(s, "<command>")) color = "green";
    if (strstr(s, "<redis>")) color = "green";
    if (strstr(s, "<reply>")) color = "cyan";
    if (strstr(s, "<error>")) color = "red";
    if (strstr(s, "<hint>")) color = "bold";
    if (strstr(s, "<value>") || strstr(s, "<retval>")) color = "magenta";
    if (len > 4 && isdigit(s[3])) {
        if (s[1] == '>')
            color = "yellow"; /* Current line. */
        else if (s[2] == '#')
            color = "bold"; /* Break point. */
    }
    return sdscatcolor(o, s, len, color);
}

static sds cliFormatReplyRaw(redisReply *r) {
    sds out = sdsempty(), tmp;
    size_t i;

    switch (r->type) {
    case REDIS_REPLY_NIL:
        /* Nothing... */
        break;
    case REDIS_REPLY_ERROR:
        out = sdscatlen(out, r->str, r->len);
        out = sdscatlen(out, "\n", 1);
        break;
    case REDIS_REPLY_STATUS:
    case REDIS_REPLY_STRING:
    case REDIS_REPLY_VERB:
        if (r->type == REDIS_REPLY_STATUS && config.eval_ldb) {
            /* The Lua debugger replies with arrays of simple (status)
             * strings. We colorize the output for more fun if this
             * is a debugging session. */

            /* Detect the end of a debugging session. */
            if (strstr(r->str, "<endsession>") == r->str) {
                config.enable_ldb_on_eval = 0;
                config.eval_ldb = 0;
                config.eval_ldb_end = 1; /* Signal the caller session ended. */
                config.output = OUTPUT_STANDARD;
                cliRefreshPrompt();
            } else {
                out = sdsCatColorizedLdbReply(out, r->str, r->len);
            }
        } else {
            out = sdscatlen(out, r->str, r->len);
        }
        break;
    case REDIS_REPLY_BOOL: out = sdscat(out, r->integer ? "(true)" : "(false)"); break;
    case REDIS_REPLY_INTEGER: out = sdscatprintf(out, "%lld", r->integer); break;
    case REDIS_REPLY_DOUBLE: out = sdscatprintf(out, "%s", r->str); break;
    case REDIS_REPLY_SET:
    case REDIS_REPLY_ARRAY:
    case REDIS_REPLY_PUSH:
        for (i = 0; i < r->elements; i++) {
            if (i > 0) out = sdscat(out, config.mb_delim);
            tmp = cliFormatReplyRaw(r->element[i]);
            out = sdscatlen(out, tmp, sdslen(tmp));
            sdsfree(tmp);
        }
        break;
    case REDIS_REPLY_MAP:
        for (i = 0; i < r->elements; i += 2) {
            if (i > 0) out = sdscat(out, config.mb_delim);
            tmp = cliFormatReplyRaw(r->element[i]);
            out = sdscatlen(out, tmp, sdslen(tmp));
            sdsfree(tmp);

            out = sdscatlen(out, " ", 1);
            tmp = cliFormatReplyRaw(r->element[i + 1]);
            out = sdscatlen(out, tmp, sdslen(tmp));
            sdsfree(tmp);
        }
        break;
    default: fprintf(stderr, "Unknown reply type: %d\n", r->type); exit(1);
    }
    return out;
}

static sds cliFormatReplyCSV(redisReply *r) {
    unsigned int i;

    sds out = sdsempty();
    switch (r->type) {
    case REDIS_REPLY_ERROR:
        out = sdscat(out, "ERROR,");
        out = sdscatrepr(out, r->str, strlen(r->str));
        break;
    case REDIS_REPLY_STATUS: out = sdscatrepr(out, r->str, r->len); break;
    case REDIS_REPLY_INTEGER: out = sdscatprintf(out, "%lld", r->integer); break;
    case REDIS_REPLY_DOUBLE: out = sdscatprintf(out, "%s", r->str); break;
    case REDIS_REPLY_STRING:
    case REDIS_REPLY_VERB: out = sdscatrepr(out, r->str, r->len); break;
    case REDIS_REPLY_NIL: out = sdscat(out, "NULL"); break;
    case REDIS_REPLY_BOOL: out = sdscat(out, r->integer ? "true" : "false"); break;
    case REDIS_REPLY_ARRAY:
    case REDIS_REPLY_SET:
    case REDIS_REPLY_PUSH:
    case REDIS_REPLY_MAP: /* CSV has no map type, just output flat list. */
        for (i = 0; i < r->elements; i++) {
            sds tmp = cliFormatReplyCSV(r->element[i]);
            out = sdscatlen(out, tmp, sdslen(tmp));
            if (i != r->elements - 1) out = sdscat(out, ",");
            sdsfree(tmp);
        }
        break;
    default: fprintf(stderr, "Unknown reply type: %d\n", r->type); exit(1);
    }
    return out;
}

/* Append specified buffer to out and return it, using required JSON output
 * mode. */
static sds jsonStringOutput(sds out, const char *p, int len, int mode) {
    if (mode == OUTPUT_JSON) {
        return escapeJsonString(out, p, len);
    } else if (mode == OUTPUT_QUOTED_JSON) {
        /* Need to double-quote backslashes */
        sds tmp = sdscatrepr(sdsempty(), p, len);
        int tmplen = sdslen(tmp);
        char *n = tmp;
        while (tmplen--) {
            if (*n == '\\')
                out = sdscatlen(out, "\\\\", 2);
            else
                out = sdscatlen(out, n, 1);
            n++;
        }

        sdsfree(tmp);
        return out;
    } else {
        assert(0);
    }
}

static sds cliFormatReplyJson(sds out, redisReply *r, int mode) {
    unsigned int i;

    switch (r->type) {
    case REDIS_REPLY_ERROR:
        out = sdscat(out, "error:");
        out = jsonStringOutput(out, r->str, strlen(r->str), mode);
        break;
    case REDIS_REPLY_STATUS: out = jsonStringOutput(out, r->str, r->len, mode); break;
    case REDIS_REPLY_INTEGER: out = sdscatprintf(out, "%lld", r->integer); break;
    case REDIS_REPLY_DOUBLE: out = sdscatprintf(out, "%s", r->str); break;
    case REDIS_REPLY_STRING:
    case REDIS_REPLY_VERB: out = jsonStringOutput(out, r->str, r->len, mode); break;
    case REDIS_REPLY_NIL: out = sdscat(out, "null"); break;
    case REDIS_REPLY_BOOL: out = sdscat(out, r->integer ? "true" : "false"); break;
    case REDIS_REPLY_ARRAY:
    case REDIS_REPLY_SET:
    case REDIS_REPLY_PUSH:
        out = sdscat(out, "[");
        for (i = 0; i < r->elements; i++) {
            out = cliFormatReplyJson(out, r->element[i], mode);
            if (i != r->elements - 1) out = sdscat(out, ",");
        }
        out = sdscat(out, "]");
        break;
    case REDIS_REPLY_MAP:
        out = sdscat(out, "{");
        for (i = 0; i < r->elements; i += 2) {
            redisReply *key = r->element[i];
            if (key->type == REDIS_REPLY_ERROR || key->type == REDIS_REPLY_STATUS || key->type == REDIS_REPLY_STRING ||
                key->type == REDIS_REPLY_VERB) {
                out = cliFormatReplyJson(out, key, mode);
            } else {
                /* According to JSON spec, JSON map keys must be strings,
                 * and in RESP3, they can be other types.
                 * The first one(cliFormatReplyJson) is to convert non string type to string
                 * The Second one(escapeJsonString) is to escape the converted string */
                sds keystr = cliFormatReplyJson(sdsempty(), key, mode);
                if (keystr[0] == '"')
                    out = sdscatsds(out, keystr);
                else
                    out = sdscatfmt(out, "\"%S\"", keystr);
                sdsfree(keystr);
            }
            out = sdscat(out, ":");

            out = cliFormatReplyJson(out, r->element[i + 1], mode);
            if (i != r->elements - 2) out = sdscat(out, ",");
        }
        out = sdscat(out, "}");
        break;
    default: fprintf(stderr, "Unknown reply type: %d\n", r->type); exit(1);
    }
    return out;
}

/* Generate reply strings in various output modes */
static sds cliFormatReply(redisReply *reply, int mode, int verbatim) {
    sds out;

    if (verbatim) {
        out = cliFormatReplyRaw(reply);
    } else if (mode == OUTPUT_STANDARD) {
        out = cliFormatReplyTTY(reply, "");
    } else if (mode == OUTPUT_RAW) {
        out = cliFormatReplyRaw(reply);
        out = sdscatsds(out, config.cmd_delim);
    } else if (mode == OUTPUT_CSV) {
        out = cliFormatReplyCSV(reply);
        out = sdscatlen(out, "\n", 1);
    } else if (mode == OUTPUT_JSON || mode == OUTPUT_QUOTED_JSON) {
        out = cliFormatReplyJson(sdsempty(), reply, mode);
        out = sdscatlen(out, "\n", 1);
    } else {
        fprintf(stderr, "Error:  Unknown output encoding %d\n", mode);
        exit(1);
    }

    return out;
}

/* Output any spontaneous PUSH reply we receive */
static void cliPushHandler(void *privdata, void *reply) {
    UNUSED(privdata);
    sds out;

    if (config.output == OUTPUT_STANDARD && isInvalidateReply(reply)) {
        out = cliFormatInvalidateTTY(reply);
    } else {
        out = cliFormatReply(reply, config.output, 0);
    }

    fwrite(out, sdslen(out), 1, stdout);

    freeReplyObject(reply);
    sdsfree(out);
}

static int cliReadReply(int output_raw_strings) {
    void *_reply;
    redisReply *reply;
    sds out = NULL;
    int output = 1;

    if (config.last_reply) {
        freeReplyObject(config.last_reply);
        config.last_reply = NULL;
    }

    if (redisGetReply(context, &_reply) != REDIS_OK) {
        if (config.blocking_state_aborted) {
            config.blocking_state_aborted = 0;
            config.monitor_mode = 0;
            config.pubsub_mode = 0;
            return cliConnect(CC_FORCE);
        }

        if (config.shutdown) {
            redisFree(context);
            context = NULL;
            return REDIS_OK;
        }
        if (config.interactive) {
            /* Filter cases where we should reconnect */
            if (context->err == REDIS_ERR_IO && (errno == ECONNRESET || errno == EPIPE)) return REDIS_ERR;
            if (context->err == REDIS_ERR_EOF) return REDIS_ERR;
        }
        cliPrintContextError();
        exit(1);
        return REDIS_ERR; /* avoid compiler warning */
    }

    config.last_reply = reply = (redisReply *)_reply;

    config.last_cmd_type = reply->type;

    /* Check if we need to connect to a different node and reissue the
     * request. */
    if (config.cluster_mode && reply->type == REDIS_REPLY_ERROR &&
        (!strncmp(reply->str, "MOVED ", 6) || !strncmp(reply->str, "ASK ", 4))) {
        char *p = reply->str, *s;
        int slot;

        output = 0;
        /* Comments show the position of the pointer as:
         *
         * [S] for pointer 's'
         * [P] for pointer 'p'
         */
        s = strchr(p, ' ');     /* MOVED[S]3999 127.0.0.1:6381 */
        p = strchr(s + 1, ' '); /* MOVED[S]3999[P]127.0.0.1:6381 */
        *p = '\0';
        slot = atoi(s + 1);
        s = strrchr(p + 1, ':'); /* MOVED 3999[P]127.0.0.1[S]6381 */
        *s = '\0';
        if (p + 1 != s) {
            /* Host might be empty, like 'MOVED 3999 :6381', if endpoint type is unknown. Only update the
             * host if it's non-empty. */
            sdsfree(config.conn_info.hostip);
            config.conn_info.hostip = sdsnew(p + 1);
        }
        config.conn_info.hostport = atoi(s + 1);
        if (config.interactive)
            printf("-> Redirected to slot [%d] located at %s:%d\n", slot, config.conn_info.hostip,
                   config.conn_info.hostport);
        config.cluster_reissue_command = 1;
        if (!strncmp(reply->str, "ASK ", 4)) {
            config.cluster_send_asking = 1;
        }
        cliRefreshPrompt();
    } else if (!config.interactive && config.set_errcode && reply->type == REDIS_REPLY_ERROR) {
        fprintf(stderr, "%s\n", reply->str);
        exit(1);
        return REDIS_ERR; /* avoid compiler warning */
    }

    if (output) {
        out = cliFormatReply(reply, config.output, output_raw_strings);
        fwrite(out, sdslen(out), 1, stdout);
        fflush(stdout);
        sdsfree(out);
    }
    return REDIS_OK;
}

/* Simultaneously wait for pubsub messages from the server and input on stdin. */
static void cliWaitForMessagesOrStdin(void) {
    int show_info = config.output != OUTPUT_RAW && (isatty(STDOUT_FILENO) || getenv("FAKETTY"));
    int use_color = show_info && isColorTerm();
    cliPressAnyKeyTTY();
    while (config.pubsub_mode) {
        /* First check if there are any buffered replies. */
        redisReply *reply;
        do {
            if (redisGetReplyFromReader(context, (void **)&reply) != REDIS_OK) {
                cliPrintContextError();
                exit(1);
            }
            if (reply) {
                sds out = cliFormatReply(reply, config.output, 0);
                fwrite(out, sdslen(out), 1, stdout);
                fflush(stdout);
                sdsfree(out);
            }
        } while (reply);

        /* Wait for input, either on the server socket or on stdin. */
        struct timeval tv;
        fd_set readfds;
        FD_ZERO(&readfds);
        FD_SET(context->fd, &readfds);
        FD_SET(STDIN_FILENO, &readfds);
        tv.tv_sec = 5;
        tv.tv_usec = 0;
        if (show_info) {
            if (use_color) printf("\033[1;90m"); /* Bold, bright color. */
            printf("Reading messages... (press Ctrl-C to quit or any key to type command)\r");
            if (use_color) printf("\033[0m"); /* Reset color. */
            fflush(stdout);
        }
        select(context->fd + 1, &readfds, NULL, NULL, &tv);
        if (show_info) {
            printf("\033[K"); /* Erase current line */
            fflush(stdout);
        }
        if (config.blocking_state_aborted) {
            /* Ctrl-C pressed */
            config.blocking_state_aborted = 0;
            config.pubsub_mode = 0;
            printf("Closing current connection. Ready to reconnect to Valkey server... \n");
            fflush(stdout);
            if (cliConnect(CC_FORCE) != REDIS_OK) {
                cliPrintContextError();
                exit(1);
            }
            break;
        } else if (FD_ISSET(context->fd, &readfds)) {
            /* Message from the server */
            if (cliReadReply(0) != REDIS_OK) {
                cliPrintContextError();
                exit(1);
            }
            fflush(stdout);
        } else if (FD_ISSET(STDIN_FILENO, &readfds)) {
            /* Any key pressed */
            break;
        }
    }
    cliRestoreTTY();
}

static int cliSendCommand(int argc, char **argv, long repeat) {
    char *command = argv[0];
    size_t *argvlen;
    int j, output_raw;

    if (context == NULL) return REDIS_ERR;

    output_raw = 0;
    if (!strcasecmp(command, "info") || !strcasecmp(command, "lolwut") ||
        (argc >= 2 && !strcasecmp(command, "debug") && !strcasecmp(argv[1], "htstats")) ||
        (argc >= 2 && !strcasecmp(command, "debug") && !strcasecmp(argv[1], "htstats-key")) ||
        (argc >= 2 && !strcasecmp(command, "debug") && !strcasecmp(argv[1], "client-eviction")) ||
        (argc >= 2 && !strcasecmp(command, "memory") &&
         (!strcasecmp(argv[1], "malloc-stats") || !strcasecmp(argv[1], "doctor"))) ||
        (argc == 2 && !strcasecmp(command, "cluster") &&
         (!strcasecmp(argv[1], "nodes") || !strcasecmp(argv[1], "info"))) ||
        (argc >= 2 && !strcasecmp(command, "client") &&
         (!strcasecmp(argv[1], "list") || !strcasecmp(argv[1], "info"))) ||
        (argc == 3 && !strcasecmp(command, "latency") && !strcasecmp(argv[1], "graph")) ||
        (argc == 2 && !strcasecmp(command, "latency") && !strcasecmp(argv[1], "doctor")) ||
        /* Format PROXY INFO command for Cluster Proxy:
         * https://github.com/artix75/redis-cluster-proxy */
        (argc >= 2 && !strcasecmp(command, "proxy") && !strcasecmp(argv[1], "info"))) {
        output_raw = 1;
    }

    if (!strcasecmp(command, "shutdown")) config.shutdown = 1;
    if (!strcasecmp(command, "monitor")) config.monitor_mode = 1;
    int is_subscribe =
        (!strcasecmp(command, "subscribe") || !strcasecmp(command, "psubscribe") || !strcasecmp(command, "ssubscribe"));
    int is_unsubscribe = (!strcasecmp(command, "unsubscribe") || !strcasecmp(command, "punsubscribe") ||
                          !strcasecmp(command, "sunsubscribe"));
    if (!strcasecmp(command, "sync") || !strcasecmp(command, "psync")) config.replica_mode = 1;

    /* When the user manually calls SCRIPT DEBUG, setup the activation of
     * debugging mode on the next eval if needed. */
    if (argc == 3 && !strcasecmp(argv[0], "script") && !strcasecmp(argv[1], "debug")) {
        if (!strcasecmp(argv[2], "yes") || !strcasecmp(argv[2], "sync")) {
            config.enable_ldb_on_eval = 1;
        } else {
            config.enable_ldb_on_eval = 0;
        }
    }

    /* Actually activate LDB on EVAL if needed. */
    if (!strcasecmp(command, "eval") && config.enable_ldb_on_eval) {
        config.eval_ldb = 1;
        config.output = OUTPUT_RAW;
    }

    /* Setup argument length */
    argvlen = zmalloc(argc * sizeof(size_t));
    for (j = 0; j < argc; j++) argvlen[j] = sdslen(argv[j]);

    /* Negative repeat is allowed and causes infinite loop,
       works well with the interval option. */
    while (repeat < 0 || repeat-- > 0) {
        redisAppendCommandArgv(context, argc, (const char **)argv, argvlen);

        if (config.monitor_mode) {
            do {
                if (cliReadReply(output_raw) != REDIS_OK) {
                    cliPrintContextError();
                    exit(1);
                }
                fflush(stdout);

                /* This happens when the MONITOR command returns an error. */
                if (config.last_cmd_type == REDIS_REPLY_ERROR) config.monitor_mode = 0;
            } while (config.monitor_mode);
            zfree(argvlen);
            return REDIS_OK;
        }

        int num_expected_pubsub_push = 0;
        if (is_subscribe || is_unsubscribe) {
            /* When a push callback is set, redisGetReply (hiredis) loops until
             * an in-band message is received, but these commands are confirmed
             * using push replies only. There is one push reply per channel if
             * channels are specified, otherwise at least one. */
            num_expected_pubsub_push = argc > 1 ? argc - 1 : 1;
            /* Unset our default PUSH handler so this works in RESP2/RESP3 */
            redisSetPushCallback(context, NULL);
        }

        if (config.replica_mode) {
            printf("Entering replica output mode...  (press Ctrl-C to quit)\n");
            replicaMode(0);
            config.replica_mode = 0;
            zfree(argvlen);
            return REDIS_ERR; /* Error = replilcaMode lost connection to primary */
        }

        /* Read response, possibly skipping pubsub/push messages. */
        while (1) {
            if (cliReadReply(output_raw) != REDIS_OK) {
                zfree(argvlen);
                return REDIS_ERR;
            }
            fflush(stdout);
            if (config.pubsub_mode || num_expected_pubsub_push > 0) {
                if (isPubsubPush(config.last_reply)) {
                    if (num_expected_pubsub_push > 0 && !strcasecmp(config.last_reply->element[0]->str, command)) {
                        /* This pushed message confirms the
                         * [p|s][un]subscribe command. */
                        if (is_subscribe && !config.pubsub_mode) {
                            config.pubsub_mode = 1;
                            cliRefreshPrompt();
                        }
                        if (--num_expected_pubsub_push > 0) {
                            continue; /* We need more of these. */
                        }
                    } else {
                        continue; /* Skip this pubsub message. */
                    }
                } else if (config.last_reply->type == REDIS_REPLY_PUSH) {
                    continue; /* Skip other push message. */
                }
            }

            /* Store database number when SELECT was successfully executed. */
            if (!strcasecmp(command, "select") && argc == 2 && config.last_cmd_type != REDIS_REPLY_ERROR) {
                config.conn_info.input_dbnum = config.dbnum = atoi(argv[1]);
                cliRefreshPrompt();
            } else if (!strcasecmp(command, "auth") && (argc == 2 || argc == 3)) {
                cliSelect();
            } else if (!strcasecmp(command, "multi") && argc == 1 && config.last_cmd_type != REDIS_REPLY_ERROR) {
                config.in_multi = 1;
                config.pre_multi_dbnum = config.dbnum;
                cliRefreshPrompt();
            } else if (!strcasecmp(command, "exec") && argc == 1 && config.in_multi) {
                config.in_multi = 0;
                if (config.last_cmd_type == REDIS_REPLY_ERROR || config.last_cmd_type == REDIS_REPLY_NIL) {
                    config.conn_info.input_dbnum = config.dbnum = config.pre_multi_dbnum;
                }
                cliRefreshPrompt();
            } else if (!strcasecmp(command, "discard") && argc == 1 && config.last_cmd_type != REDIS_REPLY_ERROR) {
                config.in_multi = 0;
                config.conn_info.input_dbnum = config.dbnum = config.pre_multi_dbnum;
                cliRefreshPrompt();
            } else if (!strcasecmp(command, "reset") && argc == 1 && config.last_cmd_type != REDIS_REPLY_ERROR) {
                config.in_multi = 0;
                config.dbnum = 0;
                config.conn_info.input_dbnum = 0;
                config.current_resp3 = 0;
                if (config.pubsub_mode && config.push_output) {
                    redisSetPushCallback(context, cliPushHandler);
                }
                config.pubsub_mode = 0;
                cliRefreshPrompt();
            } else if (!strcasecmp(command, "hello")) {
                if (config.last_cmd_type == REDIS_REPLY_MAP) {
                    config.current_resp3 = 1;
                } else if (config.last_cmd_type == REDIS_REPLY_ARRAY) {
                    config.current_resp3 = 0;
                }
            } else if ((is_subscribe || is_unsubscribe) && !config.pubsub_mode) {
                /* We didn't enter pubsub mode. Restore push callback. */
                if (config.push_output) redisSetPushCallback(context, cliPushHandler);
            }

            break;
        }
        if (config.cluster_reissue_command) {
            /* If we need to reissue the command, break to prevent a
               further 'repeat' number of dud interactions */
            break;
        }
        if (config.interval) usleep(config.interval);
        fflush(stdout); /* Make it grep friendly */
    }

    zfree(argvlen);
    return REDIS_OK;
}

/* Send a command reconnecting the link if needed. */
static redisReply *reconnectingRedisCommand(redisContext *c, const char *fmt, ...) {
    redisReply *reply = NULL;
    int tries = 0;
    va_list ap;

    assert(!c->err);
    while (reply == NULL) {
        while (c->err & (REDIS_ERR_IO | REDIS_ERR_EOF)) {
            printf("\r\x1b[0K"); /* Cursor to left edge + clear line. */
            printf("Reconnecting... %d\r", ++tries);
            fflush(stdout);

            redisFree(c);
            c = redisConnectWrapper(config.conn_info.hostip, config.conn_info.hostport, config.connect_timeout);
            if (!c->err && config.tls) {
                const char *err = NULL;
                if (cliSecureConnection(c, config.sslconfig, &err) == REDIS_ERR && err) {
                    fprintf(stderr, "TLS Error: %s\n", err);
                    exit(1);
                }
            }
            usleep(1000000);
        }

        va_start(ap, fmt);
        reply = redisvCommand(c, fmt, ap);
        va_end(ap);

        if (c->err && !(c->err & (REDIS_ERR_IO | REDIS_ERR_EOF))) {
            fprintf(stderr, "Error: %s\n", c->errstr);
            exit(1);
        } else if (tries > 0) {
            printf("\r\x1b[0K"); /* Cursor to left edge + clear line. */
        }
    }

    context = c;
    return reply;
}

/*------------------------------------------------------------------------------
 * User interface
 *--------------------------------------------------------------------------- */

static int parseOptions(int argc, char **argv) {
    int i;

    for (i = 1; i < argc; i++) {
        int lastarg = i == argc - 1;

        if (!strcmp(argv[i], "-h") && !lastarg) {
            sdsfree(config.conn_info.hostip);
            config.conn_info.hostip = sdsnew(argv[++i]);
        } else if (!strcmp(argv[i], "-h") && lastarg) {
            usage(0);
        } else if (!strcmp(argv[i], "--help")) {
            usage(0);
        } else if (!strcmp(argv[i], "-x")) {
            config.stdin_lastarg = 1;
        } else if (!strcmp(argv[i], "-X") && !lastarg) {
            config.stdin_tag_arg = 1;
            config.stdin_tag_name = argv[++i];
        } else if (!strcmp(argv[i], "-p") && !lastarg) {
            config.conn_info.hostport = atoi(argv[++i]);
            if (config.conn_info.hostport < 0 || config.conn_info.hostport > 65535) {
                fprintf(stderr, "Invalid server port.\n");
                exit(1);
            }
        } else if (!strcmp(argv[i], "-t") && !lastarg) {
            char *eptr;
            double seconds = strtod(argv[++i], &eptr);
            if (eptr[0] != '\0' || isnan(seconds) || seconds < 0.0) {
                fprintf(stderr, "Invalid connection timeout for -t.\n");
                exit(1);
            }
            config.connect_timeout.tv_sec = (long long)seconds;
            config.connect_timeout.tv_usec = ((long long)(seconds * 1000000)) % 1000000;
        } else if (!strcmp(argv[i], "-s") && !lastarg) {
            config.hostsocket = argv[++i];
        } else if (!strcmp(argv[i], "-r") && !lastarg) {
            config.repeat = strtoll(argv[++i], NULL, 10);
        } else if (!strcmp(argv[i], "-i") && !lastarg) {
            double seconds = atof(argv[++i]);
            config.interval = seconds * 1000000;
        } else if (!strcmp(argv[i], "-n") && !lastarg) {
            config.conn_info.input_dbnum = atoi(argv[++i]);
        } else if (!strcmp(argv[i], "--no-auth-warning")) {
            config.no_auth_warning = 1;
        } else if (!strcmp(argv[i], "--askpass")) {
            config.askpass = 1;
        } else if ((!strcmp(argv[i], "-a") || !strcmp(argv[i], "--pass")) && !lastarg) {
            config.conn_info.auth = sdsnew(argv[++i]);
        } else if (!strcmp(argv[i], "--user") && !lastarg) {
            config.conn_info.user = sdsnew(argv[++i]);
        } else if (!strcmp(argv[i], "-u") && !lastarg) {
            parseRedisUri(argv[++i], "valkey-cli", &config.conn_info, &config.tls);
            if (config.conn_info.hostport < 0 || config.conn_info.hostport > 65535) {
                fprintf(stderr, "Invalid server port.\n");
                exit(1);
            }
        } else if (!strcmp(argv[i], "--raw")) {
            config.output = OUTPUT_RAW;
        } else if (!strcmp(argv[i], "--no-raw")) {
            config.output = OUTPUT_STANDARD;
        } else if (!strcmp(argv[i], "--quoted-input")) {
            config.quoted_input = 1;
        } else if (!strcmp(argv[i], "--csv")) {
            config.output = OUTPUT_CSV;
        } else if (!strcmp(argv[i], "--json")) {
            /* Not overwrite explicit value by -3 */
            if (config.resp3 == 0) {
                config.resp3 = 2;
            }
            config.output = OUTPUT_JSON;
        } else if (!strcmp(argv[i], "--quoted-json")) {
            /* Not overwrite explicit value by -3*/
            if (config.resp3 == 0) {
                config.resp3 = 2;
            }
            config.output = OUTPUT_QUOTED_JSON;
        } else if (!strcmp(argv[i], "--latency")) {
            config.latency_mode = 1;
        } else if (!strcmp(argv[i], "--latency-dist")) {
            config.latency_dist_mode = 1;
        } else if (!strcmp(argv[i], "--mono")) {
            spectrum_palette = spectrum_palette_mono;
            spectrum_palette_size = spectrum_palette_mono_size;
        } else if (!strcmp(argv[i], "--latency-history")) {
            config.latency_mode = 1;
            config.latency_history = 1;
        } else if (!strcmp(argv[i], "--lru-test") && !lastarg) {
            config.lru_test_mode = 1;
            config.lru_test_sample_size = strtoll(argv[++i], NULL, 10);
        } else if (!strcmp(argv[i], "--slave") || !strcmp(argv[i], "--replica")) {
            config.replica_mode = 1;
        } else if (!strcmp(argv[i], "--stat")) {
            config.stat_mode = 1;
        } else if (!strcmp(argv[i], "--scan")) {
            config.scan_mode = 1;
        } else if (!strcmp(argv[i], "--pattern") && !lastarg) {
            sdsfree(config.pattern);
            config.pattern = sdsnew(argv[++i]);
        } else if (!strcmp(argv[i], "--count") && !lastarg) {
            config.count = atoi(argv[++i]);
        } else if (!strcmp(argv[i], "--quoted-pattern") && !lastarg) {
            sdsfree(config.pattern);
            config.pattern = unquoteCString(argv[++i]);
            if (!config.pattern) {
                fprintf(stderr, "Invalid quoted string specified for --quoted-pattern.\n");
                exit(1);
            }
        } else if (!strcmp(argv[i], "--intrinsic-latency") && !lastarg) {
            config.intrinsic_latency_mode = 1;
            config.intrinsic_latency_duration = atoi(argv[++i]);
        } else if (!strcmp(argv[i], "--rdb") && !lastarg) {
            config.getrdb_mode = 1;
            config.rdb_filename = argv[++i];
        } else if (!strcmp(argv[i], "--functions-rdb") && !lastarg) {
            config.get_functions_rdb_mode = 1;
            config.rdb_filename = argv[++i];
        } else if (!strcmp(argv[i], "--pipe")) {
            config.pipe_mode = 1;
        } else if (!strcmp(argv[i], "--pipe-timeout") && !lastarg) {
            config.pipe_timeout = atoi(argv[++i]);
        } else if (!strcmp(argv[i], "--bigkeys")) {
            config.bigkeys = 1;
        } else if (!strcmp(argv[i], "--memkeys")) {
            config.memkeys = 1;
            config.memkeys_samples = 0; /* use the server default */
        } else if (!strcmp(argv[i], "--memkeys-samples") && !lastarg) {
            config.memkeys = 1;
            config.memkeys_samples = atoi(argv[++i]);
        } else if (!strcmp(argv[i], "--hotkeys")) {
            config.hotkeys = 1;
        } else if (!strcmp(argv[i], "--eval") && !lastarg) {
            config.eval = argv[++i];
        } else if (!strcmp(argv[i], "--ldb")) {
            config.eval_ldb = 1;
            config.output = OUTPUT_RAW;
        } else if (!strcmp(argv[i], "--ldb-sync-mode")) {
            config.eval_ldb = 1;
            config.eval_ldb_sync = 1;
            config.output = OUTPUT_RAW;
        } else if (!strcmp(argv[i], "-c")) {
            config.cluster_mode = 1;
        } else if (!strcmp(argv[i], "-d") && !lastarg) {
            sdsfree(config.mb_delim);
            config.mb_delim = sdsnew(argv[++i]);
        } else if (!strcmp(argv[i], "-D") && !lastarg) {
            sdsfree(config.cmd_delim);
            config.cmd_delim = sdsnew(argv[++i]);
        } else if (!strcmp(argv[i], "-e")) {
            config.set_errcode = 1;
        } else if (!strcmp(argv[i], "--verbose")) {
            config.verbose = 1;
        } else if (!strcmp(argv[i], "-4")) {
            config.prefer_ipv4 = 1;
        } else if (!strcmp(argv[i], "-6")) {
            config.prefer_ipv6 = 1;
        } else if (!strcmp(argv[i], "--cluster") && !lastarg) {
            if (CLUSTER_MANAGER_MODE()) usage(1);
            char *cmd = argv[++i];
            int j = i;
            while (j < argc && argv[j][0] != '-') j++;
            if (j > i) j--;
            int err = createClusterManagerCommand(cmd, j - i, argv + i + 1);
            if (err) exit(err);
            i = j;
        } else if (!strcmp(argv[i], "--cluster") && lastarg) {
            usage(1);
        } else if (!strcmp(argv[i], "--cluster-only-masters") || !strcmp(argv[i], "--cluster-only-primaries")) {
            config.cluster_manager_command.flags |= CLUSTER_MANAGER_CMD_FLAG_PRIMARIES_ONLY;
        } else if ((!strcmp(argv[i], "--cluster-only-replicas"))) {
            config.cluster_manager_command.flags |= CLUSTER_MANAGER_CMD_FLAG_REPLICAS_ONLY;
        } else if (!strcmp(argv[i], "--cluster-replicas") && !lastarg) {
            config.cluster_manager_command.replicas = atoi(argv[++i]);
        } else if ((!strcmp(argv[i], "--cluster-master-id") || !strcmp(argv[i], "--cluster-primary-id")) && !lastarg) {
            config.cluster_manager_command.primary_id = argv[++i];
        } else if (!strcmp(argv[i], "--cluster-from") && !lastarg) {
            config.cluster_manager_command.from = argv[++i];
        } else if (!strcmp(argv[i], "--cluster-to") && !lastarg) {
            config.cluster_manager_command.to = argv[++i];
        } else if (!strcmp(argv[i], "--cluster-from-user") && !lastarg) {
            config.cluster_manager_command.from_user = argv[++i];
        } else if (!strcmp(argv[i], "--cluster-from-pass") && !lastarg) {
            config.cluster_manager_command.from_pass = argv[++i];
        } else if (!strcmp(argv[i], "--cluster-from-askpass")) {
            config.cluster_manager_command.from_askpass = 1;
        } else if (!strcmp(argv[i], "--cluster-weight") && !lastarg) {
            if (config.cluster_manager_command.weight != NULL) {
                fprintf(stderr, "WARNING: you cannot use --cluster-weight "
                                "more than once.\n"
                                "You can set more weights by adding them "
                                "as a space-separated list, ie:\n"
                                "--cluster-weight n1=w n2=w\n");
                exit(1);
            }
            int widx = i + 1;
            char **weight = argv + widx;
            int wargc = 0;
            for (; widx < argc; widx++) {
                if (strstr(argv[widx], "--") == argv[widx]) break;
                if (strchr(argv[widx], '=') == NULL) break;
                wargc++;
            }
            if (wargc > 0) {
                config.cluster_manager_command.weight = weight;
                config.cluster_manager_command.weight_argc = wargc;
                i += wargc;
            }
        } else if (!strcmp(argv[i], "--cluster-slots") && !lastarg) {
            config.cluster_manager_command.slots = atoi(argv[++i]);
        } else if (!strcmp(argv[i], "--cluster-timeout") && !lastarg) {
            config.cluster_manager_command.timeout = atoi(argv[++i]);
        } else if (!strcmp(argv[i], "--cluster-pipeline") && !lastarg) {
            config.cluster_manager_command.pipeline = atoi(argv[++i]);
        } else if (!strcmp(argv[i], "--cluster-threshold") && !lastarg) {
            config.cluster_manager_command.threshold = atof(argv[++i]);
        } else if (!strcmp(argv[i], "--cluster-yes")) {
            config.cluster_manager_command.flags |= CLUSTER_MANAGER_CMD_FLAG_YES;
        } else if (!strcmp(argv[i], "--cluster-simulate")) {
            config.cluster_manager_command.flags |= CLUSTER_MANAGER_CMD_FLAG_SIMULATE;
        } else if (!strcmp(argv[i], "--cluster-replace")) {
            config.cluster_manager_command.flags |= CLUSTER_MANAGER_CMD_FLAG_REPLACE;
        } else if (!strcmp(argv[i], "--cluster-copy")) {
            config.cluster_manager_command.flags |= CLUSTER_MANAGER_CMD_FLAG_COPY;
        } else if (!strcmp(argv[i], "--cluster-slave") || !strcmp(argv[i], "--cluster-replica")) {
            config.cluster_manager_command.flags |= CLUSTER_MANAGER_CMD_FLAG_REPLICA;
        } else if (!strcmp(argv[i], "--cluster-use-empty-masters") ||
                   !strcmp(argv[i], "--cluster-use-empty-primaries")) {
            config.cluster_manager_command.flags |= CLUSTER_MANAGER_CMD_FLAG_EMPTY_PRIMARY;
        } else if (!strcmp(argv[i], "--cluster-search-multiple-owners")) {
            config.cluster_manager_command.flags |= CLUSTER_MANAGER_CMD_FLAG_CHECK_OWNERS;
        } else if (!strcmp(argv[i], "--cluster-fix-with-unreachable-masters") ||
                   !strcmp(argv[i], "--cluster-fix-with-unreachable-primaries")) {
            config.cluster_manager_command.flags |= CLUSTER_MANAGER_CMD_FLAG_FIX_WITH_UNREACHABLE_PRIMARIES;
        } else if (!strcmp(argv[i], "--test_hint") && !lastarg) {
            config.test_hint = argv[++i];
        } else if (!strcmp(argv[i], "--test_hint_file") && !lastarg) {
            config.test_hint_file = argv[++i];
#ifdef USE_OPENSSL
        } else if (!strcmp(argv[i], "--tls")) {
            config.tls = 1;
        } else if (!strcmp(argv[i], "--sni") && !lastarg) {
            config.sslconfig.sni = argv[++i];
        } else if (!strcmp(argv[i], "--cacertdir") && !lastarg) {
            config.sslconfig.cacertdir = argv[++i];
        } else if (!strcmp(argv[i], "--cacert") && !lastarg) {
            config.sslconfig.cacert = argv[++i];
        } else if (!strcmp(argv[i], "--cert") && !lastarg) {
            config.sslconfig.cert = argv[++i];
        } else if (!strcmp(argv[i], "--key") && !lastarg) {
            config.sslconfig.key = argv[++i];
        } else if (!strcmp(argv[i], "--tls-ciphers") && !lastarg) {
            config.sslconfig.ciphers = argv[++i];
        } else if (!strcmp(argv[i], "--insecure")) {
            config.sslconfig.skip_cert_verify = 1;
#ifdef TLS1_3_VERSION
        } else if (!strcmp(argv[i], "--tls-ciphersuites") && !lastarg) {
            config.sslconfig.ciphersuites = argv[++i];
#endif
#endif
        } else if (!strcmp(argv[i], "-v") || !strcmp(argv[i], "--version")) {
            sds version = cliVersion();
            printf("valkey-cli %s\n", version);
            sdsfree(version);
            exit(0);
        } else if (!strcmp(argv[i], "-2")) {
            config.resp2 = 1;
        } else if (!strcmp(argv[i], "-3")) {
            config.resp3 = 1;
        } else if (!strcmp(argv[i], "--show-pushes") && !lastarg) {
            char *argval = argv[++i];
            if (!strncasecmp(argval, "n", 1)) {
                config.push_output = 0;
            } else if (!strncasecmp(argval, "y", 1)) {
                config.push_output = 1;
            } else {
                fprintf(stderr,
                        "Unknown --show-pushes value '%s' "
                        "(valid: '[y]es', '[n]o')\n",
                        argval);
            }
        } else if (CLUSTER_MANAGER_MODE() && argv[i][0] != '-') {
            if (config.cluster_manager_command.argc == 0) {
                int j = i + 1;
                while (j < argc && argv[j][0] != '-') j++;
                int cmd_argc = j - i;
                config.cluster_manager_command.argc = cmd_argc;
                config.cluster_manager_command.argv = argv + i;
                if (cmd_argc > 1) i = j - 1;
            }
        } else {
            if (argv[i][0] == '-') {
                fprintf(stderr, "Unrecognized option or bad number of args for: '%s'\n", argv[i]);
                exit(1);
            } else {
                /* Likely the command name, stop here. */
                break;
            }
        }
    }

    if (config.hostsocket && config.cluster_mode) {
        fprintf(stderr, "Options -c and -s are mutually exclusive.\n");
        exit(1);
    }

    if (config.resp2 && config.resp3 == 1) {
        fprintf(stderr, "Options -2 and -3 are mutually exclusive.\n");
        exit(1);
    }

    /* --ldb requires --eval. */
    if (config.eval_ldb && config.eval == NULL) {
        fprintf(stderr, "Options --ldb and --ldb-sync-mode require --eval.\n");
        fprintf(stderr, "Try %s --help for more information.\n", argv[0]);
        exit(1);
    }

    if (!config.no_auth_warning && config.conn_info.auth != NULL) {
        fputs("Warning: Using a password with '-a' or '-u' option on the command"
              " line interface may not be safe.\n",
              stderr);
    }

    if (config.get_functions_rdb_mode && config.getrdb_mode) {
        fprintf(stderr, "Option --functions-rdb and --rdb are mutually exclusive.\n");
        exit(1);
    }

    if (config.stdin_lastarg && config.stdin_tag_arg) {
        fprintf(stderr, "Options -x and -X are mutually exclusive.\n");
        exit(1);
    }

    if (config.prefer_ipv4 && config.prefer_ipv6) {
        fprintf(stderr, "Options -4 and -6 are mutually exclusive.\n");
        exit(1);
    }

    return i;
}

static void parseEnv(void) {
    /* Set auth from env, but do not overwrite CLI arguments if passed */
    char *auth = getenv(CLI_AUTH_ENV);
    if (auth != NULL && config.conn_info.auth == NULL) {
        config.conn_info.auth = auth;
    }

    char *cluster_yes = getenv(CLI_CLUSTER_YES_ENV);
    if (cluster_yes != NULL && !strcmp(cluster_yes, "1")) {
        config.cluster_manager_command.flags |= CLUSTER_MANAGER_CMD_FLAG_YES;
    }
}

static void usage(int err) {
    sds version = cliVersion();
    FILE *target = err ? stderr : stdout;
    /* clang-format off */
    const char *tls_usage =
#ifdef USE_OPENSSL
"  --tls              Establish a secure TLS connection.\n"
"  --sni <host>       Server name indication for TLS.\n"
"  --cacert <file>    CA Certificate file to verify with.\n"
"  --cacertdir <dir>  Directory where trusted CA certificates are stored.\n"
"                     If neither cacert nor cacertdir are specified, the default\n"
"                     system-wide trusted root certs configuration will apply.\n"
"  --insecure         Allow insecure TLS connection by skipping cert validation.\n"
"  --cert <file>      Client certificate to authenticate with.\n"
"  --key <file>       Private key file to authenticate with.\n"
"  --tls-ciphers <list> Sets the list of preferred ciphers (TLSv1.2 and below)\n"
"                     in order of preference from highest to lowest separated by colon (\":\").\n"
"                     See the ciphers(1ssl) manpage for more information about the syntax of this string.\n"
#ifdef TLS1_3_VERSION
"  --tls-ciphersuites <list> Sets the list of preferred ciphersuites (TLSv1.3)\n"
"                     in order of preference from highest to lowest separated by colon (\":\").\n"
"                     See the ciphers(1ssl) manpage for more information about the syntax of this string,\n"
"                     and specifically for TLSv1.3 ciphersuites.\n"
#endif
#endif
"";

    fprintf(target,
"valkey-cli %s\n"
"\n"
"Usage: valkey-cli [OPTIONS] [cmd [arg [arg ...]]]\n"
"  -h <hostname>      Server hostname (default: 127.0.0.1).\n"
"  -p <port>          Server port (default: 6379).\n"
"  -t <timeout>       Server connection timeout in seconds (decimals allowed).\n"
"                     Default timeout is 0, meaning no limit, depending on the OS.\n"
"  -s <socket>        Server socket (overrides hostname and port).\n"
"  -a <password>      Password to use when connecting to the server.\n"
"                     You can also use the " CLI_AUTH_ENV " environment\n"
"                     variable to pass this password more safely\n"
"                     (if both are used, this argument takes precedence).\n"
"  --user <username>  Used to send ACL style 'AUTH username pass'. Needs -a.\n"
"  --pass <password>  Alias of -a for consistency with the new --user option.\n"
"  --askpass          Force user to input password with mask from STDIN.\n"
"                     If this argument is used, '-a' and " CLI_AUTH_ENV "\n"
"                     environment variable will be ignored.\n"
"  -u <uri>           Server URI on format valkey://user:password@host:port/dbnum\n"
"                     User, password and dbnum are optional. For authentication\n"
"                     without a username, use username 'default'. For TLS, use\n"
"                     the scheme 'valkeys'.\n"
"  -r <repeat>        Execute specified command N times.\n"
"  -i <interval>      When -r is used, waits <interval> seconds per command.\n"
"                     It is possible to specify sub-second times like -i 0.1.\n"
"                     This interval is also used in --scan and --stat per cycle.\n"
"                     and in --bigkeys, --memkeys, and --hotkeys per 100 cycles.\n"
"  -n <db>            Database number.\n"
"  -2                 Start session in RESP2 protocol mode.\n"
"  -3                 Start session in RESP3 protocol mode.\n"
"  -x                 Read last argument from STDIN (see example below).\n"
"  -X                 Read <tag> argument from STDIN (see example below).\n"
"  -d <delimiter>     Delimiter between response bulks for raw formatting (default: \\n).\n"
"  -D <delimiter>     Delimiter between responses for raw formatting (default: \\n).\n"
"  -c                 Enable cluster mode (follow -ASK and -MOVED redirections).\n"
"  -e                 Return exit error code when command execution fails.\n"
"  -4                 Prefer IPv4 over IPv6 on DNS lookup.\n"
"  -6                 Prefer IPv6 over IPv4 on DNS lookup.\n"
"%s"
"  --raw              Use raw formatting for replies (default when STDOUT is\n"
"                     not a tty).\n"
"  --no-raw           Force formatted output even when STDOUT is not a tty.\n"
"  --quoted-input     Force input to be handled as quoted strings.\n"
"  --csv              Output in CSV format.\n"
"  --json             Output in JSON format (default RESP3, use -2 if you want to use with RESP2).\n"
"  --quoted-json      Same as --json, but produce ASCII-safe quoted strings, not Unicode.\n"
"  --show-pushes <yn> Whether to print RESP3 PUSH messages.  Enabled by default when\n"
"                     STDOUT is a tty but can be overridden with --show-pushes no.\n"
"  --stat             Print rolling stats about server: mem, clients, ...\n",
version,tls_usage);

    fprintf(target,
"  --latency          Enter a special mode continuously sampling latency.\n"
"                     If you use this mode in an interactive session it runs\n"
"                     forever displaying real-time stats. Otherwise if --raw or\n"
"                     --csv is specified, or if you redirect the output to a non\n"
"                     TTY, it samples the latency for 1 second (you can use\n"
"                     -i to change the interval), then produces a single output\n"
"                     and exits.\n"
"  --latency-history  Like --latency but tracking latency changes over time.\n"
"                     Default time interval is 15 sec. Change it using -i.\n"
"  --latency-dist     Shows latency as a spectrum, requires xterm 256 colors.\n"
"                     Default time interval is 1 sec. Change it using -i.\n"
"  --lru-test <keys>  Simulate a cache workload with an 80-20 distribution.\n"
"  --replica          Simulate a replica showing commands received from the primaries.\n"
"  --rdb <filename>   Transfer an RDB dump from remote server to local file.\n"
"                     Use filename of \"-\" to write to stdout.\n"
"  --functions-rdb <filename> Like --rdb but only get the functions (not the keys)\n"
"                     when getting the RDB dump file.\n"
"  --pipe             Transfer raw RESP protocol from stdin to server.\n"
"  --pipe-timeout <n> In --pipe mode, abort with error if after sending all data.\n"
"                     no reply is received within <n> seconds.\n"
"                     Default timeout: %d. Use 0 to wait forever.\n",
    CLI_DEFAULT_PIPE_TIMEOUT);
    fprintf(target,
"  --bigkeys          Sample keys looking for keys with many elements (complexity).\n"
"  --memkeys          Sample keys looking for keys consuming a lot of memory.\n"
"  --memkeys-samples <n> Sample keys looking for keys consuming a lot of memory.\n"
"                     And define number of key elements to sample\n"
"  --hotkeys          Sample keys looking for hot keys.\n"
"                     only works when maxmemory-policy is *lfu.\n"
"  --scan             List all keys using the SCAN command.\n"
"  --pattern <pat>    Keys pattern when using the --scan, --bigkeys or --hotkeys\n"
"                     options (default: *).\n"
"  --count <count>    Count option when using the --scan, --bigkeys or --hotkeys (default: 10).\n"
"  --quoted-pattern <pat> Same as --pattern, but the specified string can be\n"
"                         quoted, in order to pass an otherwise non binary-safe string.\n"
"  --intrinsic-latency <sec> Run a test to measure intrinsic system latency.\n"
"                     The test will run for the specified amount of seconds.\n"
"  --eval <file>      Send an EVAL command using the Lua script at <file>.\n"
"  --ldb              Used with --eval enable the Server Lua debugger.\n"
"  --ldb-sync-mode    Like --ldb but uses the synchronous Lua debugger, in\n"
"                     this mode the server is blocked and script changes are\n"
"                     not rolled back from the server memory.\n"
"  --cluster <command> [args...] [opts...]\n"
"                     Cluster Manager command and arguments (see below).\n"
"  --verbose          Verbose mode.\n"
"  --no-auth-warning  Don't show warning message when using password on command\n"
"                     line interface.\n"
"  --help             Output this help and exit.\n"
"  --version          Output version and exit.\n"
"\n");
    /* Using another fprintf call to avoid -Woverlength-strings compile warning */
    fprintf(target,
"Cluster Manager Commands:\n"
"  Use --cluster help to list all available cluster manager commands.\n"
"\n"
"Examples:\n"
"  valkey-cli -u valkey://default:PASSWORD@localhost:6379/0\n"
"  cat /etc/passwd | valkey-cli -x set mypasswd\n"
"  valkey-cli -D \"\" --raw dump key > key.dump && valkey-cli -X dump_tag restore key2 0 dump_tag replace < key.dump\n"
"  valkey-cli -r 100 lpush mylist x\n"
"  valkey-cli -r 100 -i 1 info | grep used_memory_human:\n"
"  valkey-cli --quoted-input set '\"null-\\x00-separated\"' value\n"
"  valkey-cli --eval myscript.lua key1 key2 , arg1 arg2 arg3\n"
"  valkey-cli --scan --pattern '*:12345*'\n"
"  valkey-cli --scan --pattern '*:12345*' --count 100\n"
"\n"
"  (Note: when using --eval the comma separates KEYS[] from ARGV[] items)\n"
"\n"
"When no command is given, valkey-cli starts in interactive mode.\n"
"Type \"help\" in interactive mode for information on available commands\n"
"and settings.\n"
"\n");
    /* clang-format on */
    sdsfree(version);
    exit(err);
}

static int confirmWithYes(char *msg, int ignore_force) {
    /* if --cluster-yes option is set and ignore_force is false,
     * do not prompt for an answer */
    if (!ignore_force && (config.cluster_manager_command.flags & CLUSTER_MANAGER_CMD_FLAG_YES)) {
        return 1;
    }

    printf("%s (type 'yes' to accept): ", msg);
    fflush(stdout);
    char buf[4];
    int nread = read(fileno(stdin), buf, 4);
    buf[3] = '\0';
    return (nread != 0 && !strcmp("yes", buf));
}

static int issueCommandRepeat(int argc, char **argv, long repeat) {
    /* In Lua debugging mode, we want to pass the "help" to the server to get
     * it's own HELP message, rather than handle it by the CLI, see ldbRepl.
     *
     * For the normal server HELP, we can process it without a connection. */
    if (!config.eval_ldb && (!strcasecmp(argv[0], "help") || !strcasecmp(argv[0], "?"))) {
        cliOutputHelp(--argc, ++argv);
        return REDIS_OK;
    }

    while (1) {
        if (config.cluster_reissue_command || context == NULL || context->err == REDIS_ERR_IO ||
            context->err == REDIS_ERR_EOF) {
            if (cliConnect(CC_FORCE) != REDIS_OK) {
                cliPrintContextError();
                config.cluster_reissue_command = 0;
                return REDIS_ERR;
            }
        }
        config.cluster_reissue_command = 0;
        if (config.cluster_send_asking) {
            if (cliSendAsking() != REDIS_OK) {
                cliPrintContextError();
                return REDIS_ERR;
            }
        }
        if (cliSendCommand(argc, argv, repeat) != REDIS_OK) {
            cliPrintContextError();
            redisFree(context);
            context = NULL;
            return REDIS_ERR;
        }

        /* Issue the command again if we got redirected in cluster mode */
        if (config.cluster_mode && config.cluster_reissue_command) {
            continue;
        }
        break;
    }
    return REDIS_OK;
}

static int issueCommand(int argc, char **argv) {
    return issueCommandRepeat(argc, argv, config.repeat);
}

/* Split the user provided command into multiple SDS arguments.
 * This function normally uses sdssplitargs() from sds.c which is able
 * to understand "quoted strings", escapes and so forth. However when
 * we are in Lua debugging mode and the "eval" command is used, we want
 * the remaining Lua script (after "e " or "eval ") to be passed verbatim
 * as a single big argument. */
static sds *cliSplitArgs(char *line, int *argc) {
    if (config.eval_ldb && (strstr(line, "eval ") == line || strstr(line, "e ") == line)) {
        sds *argv = sds_malloc(sizeof(sds) * 2);
        *argc = 2;
        int len = strlen(line);
        int elen = line[1] == ' ' ? 2 : 5; /* "e " or "eval "? */
        argv[0] = sdsnewlen(line, elen - 1);
        argv[1] = sdsnewlen(line + elen, len - elen);
        return argv;
    } else {
        return sdssplitargs(line, argc);
    }
}

/* Set the CLI preferences. This function is invoked when an interactive
 * ":command" is called, or when reading ~/.valkeyclirc file, in order to
 * set user preferences. */
void cliSetPreferences(char **argv, int argc, int interactive) {
    if (!strcasecmp(argv[0], ":set") && argc >= 2) {
        if (!strcasecmp(argv[1], "hints"))
            pref.hints = 1;
        else if (!strcasecmp(argv[1], "nohints"))
            pref.hints = 0;
        else {
            printf("%sunknown valkey-cli preference '%s'\n", interactive ? "" : ".valkeyclirc: ", argv[1]);
        }
    } else {
        printf("%sunknown valkey-cli internal command '%s'\n", interactive ? "" : ".valkeyclirc: ", argv[0]);
    }
}

/* Load the ~/.valkeyclirc file if any. */
void cliLoadPreferences(void) {
    sds rcfile = getDotfilePath(CLI_RCFILE_ENV, CLI_RCFILE_DEFAULT);
    if (rcfile == NULL) return;
    FILE *fp = fopen(rcfile, "r");
    char buf[1024];

    if (fp) {
        while (fgets(buf, sizeof(buf), fp) != NULL) {
            sds *argv;
            int argc;

            argv = sdssplitargs(buf, &argc);
            if (argc > 0) cliSetPreferences(argv, argc, 0);
            sdsfreesplitres(argv, argc);
        }
        fclose(fp);
    }
    sdsfree(rcfile);
}

/* Some commands can include sensitive information and shouldn't be put in the
 * history file. Currently these commands are include:
 * - AUTH
 * - ACL DELUSER, ACL SETUSER, ACL GETUSER
 * - CONFIG SET primaryauth/primaryuser/tls-key-file-pass/tls-client-key-file-pass/requirepass
 * - HELLO with [AUTH username password]
 * - MIGRATE with [AUTH password] or [AUTH2 username password]
 * - SENTINEL CONFIG SET sentinel-pass password, SENTINEL CONFIG SET sentinel-user username
 * - SENTINEL SET <primaryname> auth-pass password, SENTINEL SET <primaryname> auth-user username */
static int isSensitiveCommand(int argc, char **argv) {
    if (!strcasecmp(argv[0], "auth")) {
        return 1;
    } else if (argc > 1 && !strcasecmp(argv[0], "acl") &&
               (!strcasecmp(argv[1], "deluser") || !strcasecmp(argv[1], "setuser") ||
                !strcasecmp(argv[1], "getuser"))) {
        return 1;
    } else if (argc > 2 && !strcasecmp(argv[0], "config") && !strcasecmp(argv[1], "set")) {
        for (int j = 2; j < argc; j = j + 2) {
            if (!strcasecmp(argv[j], "masterauth") || !strcasecmp(argv[j], "masteruser") ||
                !strcasecmp(argv[j], "primaryuser") || !strcasecmp(argv[j], "primaryauth") ||
                !strcasecmp(argv[j], "tls-key-file-pass") || !strcasecmp(argv[j], "tls-client-key-file-pass") ||
                !strcasecmp(argv[j], "requirepass")) {
                return 1;
            }
        }
        return 0;
        /* HELLO [protover [AUTH username password] [SETNAME clientname]] */
    } else if (argc > 4 && !strcasecmp(argv[0], "hello")) {
        for (int j = 2; j < argc; j++) {
            int moreargs = argc - 1 - j;
            if (!strcasecmp(argv[j], "AUTH") && moreargs >= 2) {
                return 1;
            } else if (!strcasecmp(argv[j], "SETNAME") && moreargs) {
                j++;
            } else {
                return 0;
            }
        }
        /* MIGRATE host port key|"" destination-db timeout [COPY] [REPLACE]
         * [AUTH password] [AUTH2 username password] [KEYS key [key ...]] */
    } else if (argc > 7 && !strcasecmp(argv[0], "migrate")) {
        for (int j = 6; j < argc; j++) {
            int moreargs = argc - 1 - j;
            if (!strcasecmp(argv[j], "auth") && moreargs) {
                return 1;
            } else if (!strcasecmp(argv[j], "auth2") && moreargs >= 2) {
                return 1;
            } else if (!strcasecmp(argv[j], "keys") && moreargs) {
                return 0;
            }
        }
    } else if (argc > 4 && !strcasecmp(argv[0], "sentinel")) {
        /* SENTINEL CONFIG SET sentinel-pass password
         * SENTINEL CONFIG SET sentinel-user username */
        if (!strcasecmp(argv[1], "config") && !strcasecmp(argv[2], "set") &&
            (!strcasecmp(argv[3], "sentinel-pass") || !strcasecmp(argv[3], "sentinel-user"))) {
            return 1;
        }
        /* SENTINEL SET <primaryname> auth-pass password
         * SENTINEL SET <primaryname> auth-user username */
        if (!strcasecmp(argv[1], "set") && (!strcasecmp(argv[3], "auth-pass") || !strcasecmp(argv[3], "auth-user"))) {
            return 1;
        }
    }
    return 0;
}

static void repl(void) {
    sds historyfile = NULL;
    int history = 0;
    char *line;
    int argc;
    sds *argv;

    /* There is no need to initialize HELP when we are in lua debugger mode.
     * It has its own HELP and commands (COMMAND or COMMAND DOCS will fail and got nothing).
     * We will initialize the HELP after the Lua debugging session ended.*/
    if ((!config.eval_ldb) && isatty(fileno(stdin))) {
        /* Initialize the help using the results of the COMMAND command. */
        cliInitHelp();
    }

    config.interactive = 1;
    linenoiseSetMultiLine(1);
    linenoiseSetCompletionCallback(completionCallback);
    linenoiseSetHintsCallback(hintsCallback);
    linenoiseSetFreeHintsCallback(freeHintsCallback);

    /* Only use history and load the rc file when stdin is a tty. */
    if (isatty(fileno(stdin))) {
        historyfile = getDotfilePath(CLI_HISTFILE_ENV, CLI_HISTFILE_DEFAULT);
        // keep in-memory history always regardless if history file can be determined
        history = 1;
        if (historyfile != NULL) {
            linenoiseHistoryLoad(historyfile);
        }
        cliLoadPreferences();
    }

    cliRefreshPrompt();
    while (1) {
        line = linenoise(context ? config.prompt : "not connected> ");
        if (line == NULL) {
            /* ^C, ^D or similar. */
            if (config.pubsub_mode) {
                config.pubsub_mode = 0;
                if (cliConnect(CC_FORCE) == REDIS_OK) continue;
            }
            break;
        } else if (line[0] != '\0') {
            long repeat = 1;
            int skipargs = 0;
            char *endptr = NULL;

            argv = cliSplitArgs(line, &argc);
            if (argv == NULL) {
                printf("Invalid argument(s)\n");
                fflush(stdout);
                if (history) linenoiseHistoryAdd(line, 0);
                if (historyfile) linenoiseHistorySave(historyfile);
                linenoiseFree(line);
                continue;
            } else if (argc == 0) {
                sdsfreesplitres(argv, argc);
                linenoiseFree(line);
                continue;
            }

            /* check if we have a repeat command option and
             * need to skip the first arg */
            errno = 0;
            repeat = strtol(argv[0], &endptr, 10);
            if (argc > 1 && *endptr == '\0') {
                if (errno == ERANGE || errno == EINVAL || repeat <= 0) {
                    fputs("Invalid valkey-cli repeat command option value.\n", stdout);
                    sdsfreesplitres(argv, argc);
                    linenoiseFree(line);
                    continue;
                }
                skipargs = 1;
            } else {
                repeat = 1;
            }

            /* Always keep in-memory history. But for commands with sensitive information,
             * avoid writing them to the history file. */
            int is_sensitive = isSensitiveCommand(argc - skipargs, argv + skipargs);
            if (history) linenoiseHistoryAdd(line, is_sensitive);
            if (!is_sensitive && historyfile) linenoiseHistorySave(historyfile);

            if (strcasecmp(argv[0], "quit") == 0 || strcasecmp(argv[0], "exit") == 0) {
                exit(0);
            } else if (argv[0][0] == ':') {
                cliSetPreferences(argv, argc, 1);
                sdsfreesplitres(argv, argc);
                linenoiseFree(line);
                continue;
            } else if (strcasecmp(argv[0], "restart") == 0) {
                if (config.eval) {
                    config.eval_ldb = 1;
                    config.output = OUTPUT_RAW;
                    sdsfreesplitres(argv, argc);
                    linenoiseFree(line);
                    return; /* Return to evalMode to restart the session. */
                } else {
                    printf("Use 'restart' only in Lua debugging mode.\n");
                    fflush(stdout);
                }
            } else if (argc == 3 && !strcasecmp(argv[0], "connect")) {
                sdsfree(config.conn_info.hostip);
                config.conn_info.hostip = sdsnew(argv[1]);
                config.conn_info.hostport = atoi(argv[2]);
                cliRefreshPrompt();
                cliConnect(CC_FORCE);
            } else if (argc == 1 && !strcasecmp(argv[0], "clear")) {
                linenoiseClearScreen();
            } else {
                long long start_time = mstime(), elapsed;

                issueCommandRepeat(argc - skipargs, argv + skipargs, repeat);

                /* If our debugging session ended, show the EVAL final
                 * reply. */
                if (config.eval_ldb_end) {
                    config.eval_ldb_end = 0;
                    cliReadReply(0);
                    printf("\n(Lua debugging session ended%s)\n\n",
                           config.eval_ldb_sync ? "" : " -- dataset changes rolled back");
                    cliInitHelp();
                }

                elapsed = mstime() - start_time;
                if (elapsed >= 500 && config.output == OUTPUT_STANDARD) {
                    printf("(%.2fs)\n", (double)elapsed / 1000);
                }
            }
            /* Free the argument vector */
            sdsfreesplitres(argv, argc);
        }

        if (config.pubsub_mode) {
            cliWaitForMessagesOrStdin();
        }

        /* linenoise() returns malloc-ed lines like readline() */
        linenoiseFree(line);
    }
    exit(0);
}

static int noninteractive(int argc, char **argv) {
    int retval = 0;
    sds *sds_args = getSdsArrayFromArgv(argc, argv, config.quoted_input);

    if (!sds_args) {
        printf("Invalid quoted string\n");
        return 1;
    }

    if (config.stdin_lastarg) {
        sds_args = sds_realloc(sds_args, (argc + 1) * sizeof(sds));
        sds_args[argc] = readArgFromStdin();
        argc++;
    } else if (config.stdin_tag_arg) {
        int i = 0, tag_match = 0;

        for (; i < argc; i++) {
            if (strcmp(config.stdin_tag_name, sds_args[i]) != 0) continue;

            tag_match = 1;
            sdsfree(sds_args[i]);
            sds_args[i] = readArgFromStdin();
            break;
        }

        if (!tag_match) {
            sdsfreesplitres(sds_args, argc);
            fprintf(stderr, "Using -X option but stdin tag not match.\n");
            return 1;
        }
    }

    retval = issueCommand(argc, sds_args);
    sdsfreesplitres(sds_args, argc);
    while (config.pubsub_mode) {
        if (cliReadReply(0) != REDIS_OK) {
            cliPrintContextError();
            exit(1);
        }
        fflush(stdout);
    }
    return retval == REDIS_OK ? 0 : 1;
}

/*------------------------------------------------------------------------------
 * Eval mode
 *--------------------------------------------------------------------------- */

static int evalMode(int argc, char **argv) {
    sds script = NULL;
    FILE *fp;
    char buf[1024];
    size_t nread;
    char **argv2;
    int j, got_comma, keys;
    int retval = REDIS_OK;

    while (1) {
        if (config.eval_ldb) {
            printf("Lua debugging session started, please use:\n"
                   "quit    -- End the session.\n"
                   "restart -- Restart the script in debug mode again.\n"
                   "help    -- Show Lua script debugging commands.\n\n");
        }

        sdsfree(script);
        script = sdsempty();
        got_comma = 0;
        keys = 0;

        /* Load the script from the file, as an sds string. */
        fp = fopen(config.eval, "r");
        if (!fp) {
            fprintf(stderr, "Can't open file '%s': %s\n", config.eval, strerror(errno));
            exit(1);
        }
        while ((nread = fread(buf, 1, sizeof(buf), fp)) != 0) {
            script = sdscatlen(script, buf, nread);
        }
        fclose(fp);

        /* If we are debugging a script, enable the Lua debugger. */
        if (config.eval_ldb) {
            redisReply *reply = redisCommand(context, config.eval_ldb_sync ? "SCRIPT DEBUG sync" : "SCRIPT DEBUG yes");
            if (reply) freeReplyObject(reply);
        }

        /* Create our argument vector */
        argv2 = zmalloc(sizeof(sds) * (argc + 3));
        argv2[0] = sdsnew("EVAL");
        argv2[1] = script;
        for (j = 0; j < argc; j++) {
            if (!got_comma && argv[j][0] == ',' && argv[j][1] == 0) {
                got_comma = 1;
                continue;
            }
            argv2[j + 3 - got_comma] = sdsnew(argv[j]);
            if (!got_comma) keys++;
        }
        argv2[2] = sdscatprintf(sdsempty(), "%d", keys);

        /* Call it */
        int eval_ldb = config.eval_ldb; /* Save it, may be reverted. */
        retval = issueCommand(argc + 3 - got_comma, argv2);
        if (eval_ldb) {
            if (!config.eval_ldb) {
                /* If the debugging session ended immediately, there was an
                 * error compiling the script. Show it and they don't enter
                 * the REPL at all. */
                printf("Eval debugging session can't start:\n");
                cliReadReply(0);
                break; /* Return to the caller. */
            } else {
                strncpy(config.prompt, "lua debugger> ", sizeof(config.prompt));
                repl();
                /* Restart the session if repl() returned. */
                cliConnect(CC_FORCE);
                printf("\n");
            }
        } else {
            break; /* Return to the caller. */
        }
    }
    return retval == REDIS_OK ? 0 : 1;
}

/*------------------------------------------------------------------------------
 * Cluster Manager
 *--------------------------------------------------------------------------- */

/* The Cluster Manager global structure */
static struct clusterManager {
    list *nodes; /* List of nodes in the configuration. */
    list *errors;
    int unreachable_primaries; /* Primaries we are not able to reach. */
} cluster_manager;

/* Used by clusterManagerFixSlotsCoverage */
dict *clusterManagerUncoveredSlots = NULL;

typedef struct clusterManagerNode {
    redisContext *context;
    sds name;
    char *ip;
    int port;
    int bus_port; /* cluster-port */
    uint64_t current_epoch;
    time_t ping_sent;
    time_t ping_recv;
    int flags;
    list *flags_str; /* Flags string representations */
    sds replicate;   /* Primary ID if node is a replica */
    int dirty;       /* Node has changes that can be flushed */
    uint8_t slots[CLUSTER_MANAGER_SLOTS];
    int slots_count;
    int replicas_count;
    list *friends;
    sds *migrating;      /* An array of sds where even strings are slots and odd
                          * strings are the destination node IDs. */
    sds *importing;      /* An array of sds where even strings are slots and odd
                          * strings are the source node IDs. */
    int migrating_count; /* Length of the migrating array (migrating slots*2) */
    int importing_count; /* Length of the importing array (importing slots*2) */
    float weight;        /* Weight used by rebalance */
    int balance;         /* Used by rebalance */
} clusterManagerNode;

/* Data structure used to represent a sequence of cluster nodes. */
typedef struct clusterManagerNodeArray {
    clusterManagerNode **nodes; /* Actual nodes array */
    clusterManagerNode **alloc; /* Pointer to the allocated memory */
    int len;                    /* Actual length of the array */
    int count;                  /* Non-NULL nodes count */
} clusterManagerNodeArray;

/* Used for the reshard table. */
typedef struct clusterManagerReshardTableItem {
    clusterManagerNode *source;
    int slot;
} clusterManagerReshardTableItem;

/* Info about a cluster internal link. */

typedef struct clusterManagerLink {
    sds node_name;
    sds node_addr;
    int connected;
    int handshaking;
} clusterManagerLink;

static dictType clusterManagerDictType = {
    dictSdsHash,       /* hash function */
    NULL,              /* key dup */
    dictSdsKeyCompare, /* key compare */
    NULL,              /* key destructor */
    dictSdsDestructor, /* val destructor */
    NULL               /* allow to expand */
};

static dictType clusterManagerLinkDictType = {
    dictSdsHash,        /* hash function */
    NULL,               /* key dup */
    dictSdsKeyCompare,  /* key compare */
    dictSdsDestructor,  /* key destructor */
    dictListDestructor, /* val destructor */
    NULL                /* allow to expand */
};

typedef int clusterManagerCommandProc(int argc, char **argv);
typedef int (*clusterManagerOnReplyError)(redisReply *reply, clusterManagerNode *n, int bulk_idx);

/* Cluster Manager helper functions */

static clusterManagerNode *clusterManagerNewNode(char *ip, int port, int bus_port);
static clusterManagerNode *clusterManagerNodeByName(const char *name);
static clusterManagerNode *clusterManagerNodeByAbbreviatedName(const char *n);
static void clusterManagerNodeResetSlots(clusterManagerNode *node);
static int clusterManagerNodeIsCluster(clusterManagerNode *node, char **err);
static void clusterManagerPrintNotClusterNodeError(clusterManagerNode *node, char *err);
static int clusterManagerNodeLoadInfo(clusterManagerNode *node, int opts, char **err);
static int clusterManagerLoadInfoFromNode(clusterManagerNode *node);
static int clusterManagerNodeIsEmpty(clusterManagerNode *node, char **err);
static int clusterManagerGetAntiAffinityScore(clusterManagerNodeArray *ipnodes,
                                              int ip_count,
                                              clusterManagerNode ***offending,
                                              int *offending_len);
static void clusterManagerOptimizeAntiAffinity(clusterManagerNodeArray *ipnodes, int ip_count);
static sds clusterManagerNodeInfo(clusterManagerNode *node, int indent);
static void clusterManagerShowNodes(void);
static void clusterManagerShowClusterInfo(void);
static int clusterManagerFlushNodeConfig(clusterManagerNode *node, char **err);
static void clusterManagerWaitForClusterJoin(void);
static int clusterManagerCheckCluster(int quiet);
static void clusterManagerLog(int level, const char *fmt, ...);
static int clusterManagerIsConfigConsistent(void);
static dict *clusterManagerGetLinkStatus(void);
static void clusterManagerOnError(sds err);
static void clusterManagerNodeArrayInit(clusterManagerNodeArray *array, int len);
static void clusterManagerNodeArrayReset(clusterManagerNodeArray *array);
static void clusterManagerNodeArrayShift(clusterManagerNodeArray *array, clusterManagerNode **nodeptr);
static void clusterManagerNodeArrayAdd(clusterManagerNodeArray *array, clusterManagerNode *node);

/* Cluster Manager commands. */

static int clusterManagerCommandCreate(int argc, char **argv);
static int clusterManagerCommandAddNode(int argc, char **argv);
static int clusterManagerCommandDeleteNode(int argc, char **argv);
static int clusterManagerCommandInfo(int argc, char **argv);
static int clusterManagerCommandCheck(int argc, char **argv);
static int clusterManagerCommandFix(int argc, char **argv);
static int clusterManagerCommandReshard(int argc, char **argv);
static int clusterManagerCommandRebalance(int argc, char **argv);
static int clusterManagerCommandSetTimeout(int argc, char **argv);
static int clusterManagerCommandImport(int argc, char **argv);
static int clusterManagerCommandCall(int argc, char **argv);
static int clusterManagerCommandHelp(int argc, char **argv);
static int clusterManagerCommandBackup(int argc, char **argv);

typedef struct clusterManagerCommandDef {
    char *name;
    clusterManagerCommandProc *proc;
    int arity;
    char *args;
    char *options;
} clusterManagerCommandDef;

clusterManagerCommandDef clusterManagerCommands[] = {
    {"create", clusterManagerCommandCreate, -1, "host1:port1 ... hostN:portN", "replicas <arg>"},
    {"check", clusterManagerCommandCheck, -1, "<host:port> or <host> <port> - separated by either colon or space",
     "search-multiple-owners"},
    {"info", clusterManagerCommandInfo, -1, "<host:port> or <host> <port> - separated by either colon or space", NULL},
    {"fix", clusterManagerCommandFix, -1, "<host:port> or <host> <port> - separated by either colon or space",
     "search-multiple-owners,fix-with-unreachable-primaries"},
    {"reshard", clusterManagerCommandReshard, -1, "<host:port> or <host> <port> - separated by either colon or space",
     "from <arg>,to <arg>,slots <arg>,yes,timeout <arg>,pipeline <arg>,"
     "replace"},
    {"rebalance", clusterManagerCommandRebalance, -1,
     "<host:port> or <host> <port> - separated by either colon or space",
     "weight <node1=w1...nodeN=wN>,use-empty-primaries,"
     "timeout <arg>,simulate,pipeline <arg>,threshold <arg>,replace"},
    {"add-node", clusterManagerCommandAddNode, 2, "new_host:new_port existing_host:existing_port",
     "replica,primaries-id <arg>"},
    {"del-node", clusterManagerCommandDeleteNode, 2, "host:port node_id", NULL},
    {"call", clusterManagerCommandCall, -2, "host:port command arg arg .. arg", "only-primaries,only-replicas"},
    {"set-timeout", clusterManagerCommandSetTimeout, 2, "host:port milliseconds", NULL},
    {"import", clusterManagerCommandImport, 1, "host:port",
     "from <arg>,from-user <arg>,from-pass <arg>,from-askpass,copy,replace"},
    {"backup", clusterManagerCommandBackup, 2, "host:port backup_directory", NULL},
    {"help", clusterManagerCommandHelp, 0, NULL, NULL}};

typedef struct clusterManagerOptionDef {
    char *name;
    char *desc;
} clusterManagerOptionDef;

clusterManagerOptionDef clusterManagerOptions[] = {{"--cluster-yes", "Automatic yes to cluster commands prompts"}};

static void getRDB(clusterManagerNode *node);

static int createClusterManagerCommand(char *cmdname, int argc, char **argv) {
    clusterManagerCommand *cmd = &config.cluster_manager_command;
    cmd->name = cmdname;
    cmd->argc = argc;
    cmd->argv = argc ? argv : NULL;
    if (isColorTerm()) cmd->flags |= CLUSTER_MANAGER_CMD_FLAG_COLOR;

    if (config.stdin_lastarg) {
        char **new_argv = zmalloc(sizeof(char *) * (cmd->argc + 1));
        memcpy(new_argv, cmd->argv, sizeof(char *) * cmd->argc);

        cmd->stdin_arg = readArgFromStdin();
        new_argv[cmd->argc++] = cmd->stdin_arg;
        cmd->argv = new_argv;
    } else if (config.stdin_tag_arg) {
        int i = 0, tag_match = 0;
        cmd->stdin_arg = readArgFromStdin();

        for (; i < argc; i++) {
            if (strcmp(argv[i], config.stdin_tag_name) != 0) continue;

            tag_match = 1;
            cmd->argv[i] = (char *)cmd->stdin_arg;
            break;
        }

        if (!tag_match) {
            sdsfree(cmd->stdin_arg);
            fprintf(stderr, "Using -X option but stdin tag not match.\n");
            return 1;
        }
    }

    return 0;
}

static clusterManagerCommandProc *validateClusterManagerCommand(void) {
    int i, commands_count = sizeof(clusterManagerCommands) / sizeof(clusterManagerCommandDef);
    clusterManagerCommandProc *proc = NULL;
    char *cmdname = config.cluster_manager_command.name;
    int argc = config.cluster_manager_command.argc;
    for (i = 0; i < commands_count; i++) {
        clusterManagerCommandDef cmddef = clusterManagerCommands[i];
        if (!strcmp(cmddef.name, cmdname)) {
            if ((cmddef.arity > 0 && argc != cmddef.arity) || (cmddef.arity < 0 && argc < (cmddef.arity * -1))) {
                fprintf(stderr, "[ERR] Wrong number of arguments for "
                                "specified --cluster sub command\n");
                return NULL;
            }
            proc = cmddef.proc;
        }
    }
    if (!proc) fprintf(stderr, "Unknown --cluster subcommand\n");
    return proc;
}

static int parseClusterNodeAddress(char *addr, char **ip_ptr, int *port_ptr, int *bus_port_ptr) {
    /* ip:port[@bus_port] */
    char *c = strrchr(addr, '@');
    if (c != NULL) {
        *c = '\0';
        if (bus_port_ptr != NULL) *bus_port_ptr = atoi(c + 1);
    }
    c = strrchr(addr, ':');
    if (c != NULL) {
        *c = '\0';
        *ip_ptr = addr;
        *port_ptr = atoi(++c);
    } else
        return 0;
    return 1;
}

/* Get host ip and port from command arguments. If only one argument has
 * been provided it must be in the form of 'ip:port', elsewhere
 * the first argument must be the ip and the second one the port.
 * If host and port can be detected, it returns 1 and it stores host and
 * port into variables referenced by 'ip_ptr' and 'port_ptr' pointers,
 * elsewhere it returns 0. */
static int getClusterHostFromCmdArgs(int argc, char **argv, char **ip_ptr, int *port_ptr) {
    int port = 0;
    char *ip = NULL;
    if (argc == 1) {
        char *addr = argv[0];
        if (!parseClusterNodeAddress(addr, &ip, &port, NULL)) return 0;
    } else {
        ip = argv[0];
        port = atoi(argv[1]);
    }
    if (!ip || !port)
        return 0;
    else {
        *ip_ptr = ip;
        *port_ptr = port;
    }
    return 1;
}

static void freeClusterManagerNodeFlags(list *flags) {
    listIter li;
    listNode *ln;
    listRewind(flags, &li);
    while ((ln = listNext(&li)) != NULL) {
        sds flag = ln->value;
        sdsfree(flag);
    }
    listRelease(flags);
}

static void freeClusterManagerNode(clusterManagerNode *node) {
    if (node->context != NULL) redisFree(node->context);
    if (node->friends != NULL) {
        listIter li;
        listNode *ln;
        listRewind(node->friends, &li);
        while ((ln = listNext(&li)) != NULL) {
            clusterManagerNode *fn = ln->value;
            freeClusterManagerNode(fn);
        }
        listRelease(node->friends);
        node->friends = NULL;
    }
    if (node->name != NULL) sdsfree(node->name);
    if (node->replicate != NULL) sdsfree(node->replicate);
    if ((node->flags & CLUSTER_MANAGER_FLAG_FRIEND) && node->ip) sdsfree(node->ip);
    int i;
    if (node->migrating != NULL) {
        for (i = 0; i < node->migrating_count; i++) sdsfree(node->migrating[i]);
        zfree(node->migrating);
    }
    if (node->importing != NULL) {
        for (i = 0; i < node->importing_count; i++) sdsfree(node->importing[i]);
        zfree(node->importing);
    }
    if (node->flags_str != NULL) {
        freeClusterManagerNodeFlags(node->flags_str);
        node->flags_str = NULL;
    }
    zfree(node);
}

static void freeClusterManager(void) {
    listIter li;
    listNode *ln;
    if (cluster_manager.nodes != NULL) {
        listRewind(cluster_manager.nodes, &li);
        while ((ln = listNext(&li)) != NULL) {
            clusterManagerNode *n = ln->value;
            freeClusterManagerNode(n);
        }
        listRelease(cluster_manager.nodes);
        cluster_manager.nodes = NULL;
    }
    if (cluster_manager.errors != NULL) {
        listRewind(cluster_manager.errors, &li);
        while ((ln = listNext(&li)) != NULL) {
            sds err = ln->value;
            sdsfree(err);
        }
        listRelease(cluster_manager.errors);
        cluster_manager.errors = NULL;
    }
    if (clusterManagerUncoveredSlots != NULL) dictRelease(clusterManagerUncoveredSlots);
}

static clusterManagerNode *clusterManagerNewNode(char *ip, int port, int bus_port) {
    clusterManagerNode *node = zmalloc(sizeof(*node));
    node->context = NULL;
    node->name = NULL;
    node->ip = ip;
    node->port = port;
    /* We don't need to know the bus_port, at this point this value may be wrong.
     * If it is used, it will be corrected in clusterManagerLoadInfoFromNode. */
    node->bus_port = bus_port ? bus_port : port + CLUSTER_MANAGER_PORT_INCR;
    node->current_epoch = 0;
    node->ping_sent = 0;
    node->ping_recv = 0;
    node->flags = 0;
    node->flags_str = NULL;
    node->replicate = NULL;
    node->dirty = 0;
    node->friends = NULL;
    node->migrating = NULL;
    node->importing = NULL;
    node->migrating_count = 0;
    node->importing_count = 0;
    node->replicas_count = 0;
    node->weight = 1.0f;
    node->balance = 0;
    clusterManagerNodeResetSlots(node);
    return node;
}

static sds clusterManagerGetNodeRDBFilename(clusterManagerNode *node) {
    assert(config.cluster_manager_command.backup_dir);
    sds filename = sdsnew(config.cluster_manager_command.backup_dir);
    if (filename[sdslen(filename) - 1] != '/') filename = sdscat(filename, "/");
    filename = sdscatprintf(filename, "valkey-node-%s-%d-%s.rdb", node->ip, node->port, node->name);
    return filename;
}

/* Check whether reply is NULL or its type is REDIS_REPLY_ERROR. In the
 * latest case, if the 'err' arg is not NULL, it gets allocated with a copy
 * of reply error (it's up to the caller function to free it), elsewhere
 * the error is directly printed. */
static int clusterManagerCheckRedisReply(clusterManagerNode *n, redisReply *r, char **err) {
    int is_err = 0;
    if (!r || (is_err = (r->type == REDIS_REPLY_ERROR))) {
        if (is_err) {
            if (err != NULL) {
                *err = zmalloc((r->len + 1) * sizeof(char));
                valkey_strlcpy(*err, r->str, (r->len + 1));
            } else
                CLUSTER_MANAGER_PRINT_REPLY_ERROR(n, r->str);
        }
        return 0;
    }
    return 1;
}

/* Call MULTI command on a cluster node. */
static int clusterManagerStartTransaction(clusterManagerNode *node) {
    redisReply *reply = CLUSTER_MANAGER_COMMAND(node, "MULTI");
    int success = clusterManagerCheckRedisReply(node, reply, NULL);
    if (reply) freeReplyObject(reply);
    return success;
}

/* Call EXEC command on a cluster node. */
static int clusterManagerExecTransaction(clusterManagerNode *node, clusterManagerOnReplyError onerror) {
    redisReply *reply = CLUSTER_MANAGER_COMMAND(node, "EXEC");
    int success = clusterManagerCheckRedisReply(node, reply, NULL);
    if (success) {
        if (reply->type != REDIS_REPLY_ARRAY) {
            success = 0;
            goto cleanup;
        }
        size_t i;
        for (i = 0; i < reply->elements; i++) {
            redisReply *r = reply->element[i];
            char *err = NULL;
            success = clusterManagerCheckRedisReply(node, r, &err);
            if (!success && onerror) success = onerror(r, node, i);
            if (err) {
                if (!success) CLUSTER_MANAGER_PRINT_REPLY_ERROR(node, err);
                zfree(err);
            }
            if (!success) break;
        }
    }
cleanup:
    if (reply) freeReplyObject(reply);
    return success;
}

static int clusterManagerNodeConnect(clusterManagerNode *node) {
    if (node->context) redisFree(node->context);
    node->context = redisConnectWrapper(node->ip, node->port, config.connect_timeout);
    if (!node->context->err && config.tls) {
        const char *err = NULL;
        if (cliSecureConnection(node->context, config.sslconfig, &err) == REDIS_ERR && err) {
            fprintf(stderr, "TLS Error: %s\n", err);
            redisFree(node->context);
            node->context = NULL;
            return 0;
        }
    }
    if (node->context->err) {
        fprintf(stderr, "Could not connect to Valkey at ");
        fprintf(stderr, "%s:%d: %s\n", node->ip, node->port, node->context->errstr);
        redisFree(node->context);
        node->context = NULL;
        return 0;
    }
    /* Set aggressive KEEP_ALIVE socket option in the server context socket
     * in order to prevent timeouts caused by the execution of long
     * commands. At the same time this improves the detection of real
     * errors. */
    anetKeepAlive(NULL, node->context->fd, CLI_KEEPALIVE_INTERVAL);
    if (config.conn_info.auth) {
        redisReply *reply;
        if (config.conn_info.user == NULL)
            reply = redisCommand(node->context, "AUTH %s", config.conn_info.auth);
        else
            reply = redisCommand(node->context, "AUTH %s %s", config.conn_info.user, config.conn_info.auth);
        int ok = clusterManagerCheckRedisReply(node, reply, NULL);
        if (reply != NULL) freeReplyObject(reply);
        if (!ok) return 0;
    }
    return 1;
}

static void clusterManagerRemoveNodeFromList(list *nodelist, clusterManagerNode *node) {
    listIter li;
    listNode *ln;
    listRewind(nodelist, &li);
    while ((ln = listNext(&li)) != NULL) {
        if (node == ln->value) {
            listDelNode(nodelist, ln);
            break;
        }
    }
}

/* Return the node with the specified name (ID) or NULL. */
static clusterManagerNode *clusterManagerNodeByName(const char *name) {
    if (cluster_manager.nodes == NULL) return NULL;
    clusterManagerNode *found = NULL;
    sds lcname = sdsempty();
    lcname = sdscpy(lcname, name);
    sdstolower(lcname);
    listIter li;
    listNode *ln;
    listRewind(cluster_manager.nodes, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *n = ln->value;
        if (n->name && !sdscmp(n->name, lcname)) {
            found = n;
            break;
        }
    }
    sdsfree(lcname);
    return found;
}

/* Like clusterManagerNodeByName but the specified name can be just the first
 * part of the node ID as long as the prefix in unique across the
 * cluster.
 */
static clusterManagerNode *clusterManagerNodeByAbbreviatedName(const char *name) {
    if (cluster_manager.nodes == NULL) return NULL;
    clusterManagerNode *found = NULL;
    sds lcname = sdsempty();
    lcname = sdscpy(lcname, name);
    sdstolower(lcname);
    listIter li;
    listNode *ln;
    listRewind(cluster_manager.nodes, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *n = ln->value;
        if (n->name && strstr(n->name, lcname) == n->name) {
            found = n;
            break;
        }
    }
    sdsfree(lcname);
    return found;
}

static void clusterManagerNodeResetSlots(clusterManagerNode *node) {
    memset(node->slots, 0, sizeof(node->slots));
    node->slots_count = 0;
}

/* Call "INFO" command on the specified node and return the reply. */
static redisReply *clusterManagerGetNodeRedisInfo(clusterManagerNode *node, char **err) {
    redisReply *info = CLUSTER_MANAGER_COMMAND(node, "INFO");
    if (err != NULL) *err = NULL;
    if (info == NULL) return NULL;
    if (info->type == REDIS_REPLY_ERROR) {
        if (err != NULL) {
            *err = zmalloc((info->len + 1) * sizeof(char));
            valkey_strlcpy(*err, info->str, (info->len + 1));
        }
        freeReplyObject(info);
        return NULL;
    }
    return info;
}

static int clusterManagerNodeIsCluster(clusterManagerNode *node, char **err) {
    redisReply *info = clusterManagerGetNodeRedisInfo(node, err);
    if (info == NULL) return 0;
    int is_cluster = (int)getLongInfoField(info->str, "cluster_enabled");
    freeReplyObject(info);
    return is_cluster;
}

/* Checks whether the node is empty. Node is considered not-empty if it has
 * some key or if it already knows other nodes */
static int clusterManagerNodeIsEmpty(clusterManagerNode *node, char **err) {
    redisReply *info = clusterManagerGetNodeRedisInfo(node, err);
    int is_empty = 1;
    if (info == NULL) return 0;
    if (strstr(info->str, "db0:") != NULL) {
        is_empty = 0;
        goto result;
    }
    freeReplyObject(info);
    info = CLUSTER_MANAGER_COMMAND(node, "CLUSTER INFO");
    if (err != NULL) *err = NULL;
    if (!clusterManagerCheckRedisReply(node, info, err)) {
        is_empty = 0;
        goto result;
    }
    long known_nodes = getLongInfoField(info->str, "cluster_known_nodes");
    is_empty = (known_nodes == 1);
result:
    freeReplyObject(info);
    return is_empty;
}

/* Return the anti-affinity score, which is a measure of the amount of
 * violations of anti-affinity in the current cluster layout, that is, how
 * badly the primaries and replicas are distributed in the different IP
 * addresses so that replicas of the same primary are not in the primary
 * host and are also in different hosts.
 *
 * The score is calculated as follows:
 *
 * SAME_AS_PRIMARY = 10000 * each replica in the same IP of its primary.
 * SAME_AS_REPLICA  = 1 * each replica having the same IP as another replica
                      of the same primary.
 * FINAL_SCORE = SAME_AS_PRIMARY + SAME_AS_REPLICA
 *
 * So a greater score means a worse anti-affinity level, while zero
 * means perfect anti-affinity.
 *
 * The anti affinity optimization will try to get a score as low as
 * possible. Since we do not want to sacrifice the fact that replicas should
 * not be in the same host as the primary, we assign 10000 times the score
 * to this violation, so that we'll optimize for the second factor only
 * if it does not impact the first one.
 *
 * The ipnodes argument is an array of clusterManagerNodeArray, one for
 * each IP, while ip_count is the total number of IPs in the configuration.
 *
 * The function returns the above score, and the list of
 * offending replicas can be stored into the 'offending' argument,
 * so that the optimizer can try changing the configuration of the
 * replicas violating the anti-affinity goals. */
static int clusterManagerGetAntiAffinityScore(clusterManagerNodeArray *ipnodes,
                                              int ip_count,
                                              clusterManagerNode ***offending,
                                              int *offending_len) {
    int score = 0, i, j;
    int node_len = cluster_manager.nodes->len;
    clusterManagerNode **offending_p = NULL;
    if (offending != NULL) {
        *offending = zcalloc(node_len * sizeof(clusterManagerNode *));
        offending_p = *offending;
    }
    /* For each set of nodes in the same host, split by
     * related nodes (primaries and replicas which are involved in
     * replication of each other) */
    for (i = 0; i < ip_count; i++) {
        clusterManagerNodeArray *node_array = &(ipnodes[i]);
        dict *related = dictCreate(&clusterManagerDictType);
        char *ip = NULL;
        for (j = 0; j < node_array->len; j++) {
            clusterManagerNode *node = node_array->nodes[j];
            if (node == NULL) continue;
            if (!ip) ip = node->ip;
            sds types;
            /* We always use the Primary ID as key. */
            sds key = (!node->replicate ? node->name : node->replicate);
            assert(key != NULL);
            dictEntry *entry = dictFind(related, key);
            if (entry)
                types = sdsdup((sds)dictGetVal(entry));
            else
                types = sdsempty();
            /* Primary type 'm' is always set as the first character of the
             * types string. */
            if (node->replicate)
                types = sdscat(types, "s");
            else {
                sds s = sdscatsds(sdsnew("m"), types);
                sdsfree(types);
                types = s;
            }
            dictReplace(related, key, types);
        }
        /* Now it's trivial to check, for each related group having the
         * same host, what is their local score. */
        dictIterator *iter = dictGetIterator(related);
        dictEntry *entry;
        while ((entry = dictNext(iter)) != NULL) {
            sds types = (sds)dictGetVal(entry);
            sds name = (sds)dictGetKey(entry);
            int typeslen = sdslen(types);
            if (typeslen < 2) continue;
            if (types[0] == 'm')
                score += (10000 * (typeslen - 1));
            else
                score += (1 * typeslen);
            if (offending == NULL) continue;
            /* Populate the list of offending nodes. */
            listIter li;
            listNode *ln;
            listRewind(cluster_manager.nodes, &li);
            while ((ln = listNext(&li)) != NULL) {
                clusterManagerNode *n = ln->value;
                if (n->replicate == NULL) continue;
                if (!strcmp(n->replicate, name) && !strcmp(n->ip, ip)) {
                    *(offending_p++) = n;
                    if (offending_len != NULL) (*offending_len)++;
                    break;
                }
            }
        }
        // if (offending_len != NULL) *offending_len = offending_p - *offending;
        dictReleaseIterator(iter);
        dictRelease(related);
    }
    return score;
}

static void clusterManagerOptimizeAntiAffinity(clusterManagerNodeArray *ipnodes, int ip_count) {
    clusterManagerNode **offenders = NULL;
    int score = clusterManagerGetAntiAffinityScore(ipnodes, ip_count, NULL, NULL);
    if (score == 0) goto cleanup;
    clusterManagerLogInfo(">>> Trying to optimize replicas allocation "
                          "for anti-affinity\n");
    int node_len = cluster_manager.nodes->len;
    int maxiter = 500 * node_len; // Effort is proportional to cluster size...
    srand(time(NULL));
    while (maxiter > 0) {
        int offending_len = 0;
        if (offenders != NULL) {
            zfree(offenders);
            offenders = NULL;
        }
        score = clusterManagerGetAntiAffinityScore(ipnodes, ip_count, &offenders, &offending_len);
        if (score == 0 || offending_len == 0) break; // Optimal anti affinity reached
        /* We'll try to randomly swap a replica's assigned primary causing
         * an affinity problem with another random replica, to see if we
         * can improve the affinity. */
        int rand_idx = rand() % offending_len;
        clusterManagerNode *first = offenders[rand_idx], *second = NULL;
        clusterManagerNode **other_replicas = zcalloc((node_len - 1) * sizeof(*other_replicas));
        int other_replicas_count = 0;
        listIter li;
        listNode *ln;
        listRewind(cluster_manager.nodes, &li);
        while ((ln = listNext(&li)) != NULL) {
            clusterManagerNode *n = ln->value;
            if (n != first && n->replicate != NULL) other_replicas[other_replicas_count++] = n;
        }
        if (other_replicas_count == 0) {
            zfree(other_replicas);
            break;
        }
        rand_idx = rand() % other_replicas_count;
        second = other_replicas[rand_idx];
        char *first_primary = first->replicate, *second_primary = second->replicate;
        first->replicate = second_primary, first->dirty = 1;
        second->replicate = first_primary, second->dirty = 1;
        int new_score = clusterManagerGetAntiAffinityScore(ipnodes, ip_count, NULL, NULL);
        /* If the change actually makes thing worse, revert. Otherwise
         * leave as it is because the best solution may need a few
         * combined swaps. */
        if (new_score > score) {
            first->replicate = first_primary;
            second->replicate = second_primary;
        }
        zfree(other_replicas);
        maxiter--;
    }
    score = clusterManagerGetAntiAffinityScore(ipnodes, ip_count, NULL, NULL);
    char *msg;
    int perfect = (score == 0);
    int log_level = (perfect ? CLUSTER_MANAGER_LOG_LVL_SUCCESS : CLUSTER_MANAGER_LOG_LVL_WARN);
    if (perfect)
        msg = "[OK] Perfect anti-affinity obtained!";
    else if (score >= 10000)
        msg = ("[WARNING] Some replicsa are in the same host as their primary");
    else
        msg = ("[WARNING] Some replicas of the same primary are in the same host");
    clusterManagerLog(log_level, "%s\n", msg);
cleanup:
    zfree(offenders);
}

/* Return a representable string of the node's flags */
static sds clusterManagerNodeFlagString(clusterManagerNode *node) {
    sds flags = sdsempty();
    if (!node->flags_str) return flags;
    int empty = 1;
    listIter li;
    listNode *ln;
    listRewind(node->flags_str, &li);
    while ((ln = listNext(&li)) != NULL) {
        sds flag = ln->value;
        if (strcmp(flag, "myself") == 0) continue;
        if (!empty) flags = sdscat(flags, ",");
        flags = sdscatfmt(flags, "%S", flag);
        empty = 0;
    }
    return flags;
}

/* Return a representable string of the node's slots */
static sds clusterManagerNodeSlotsString(clusterManagerNode *node) {
    sds slots = sdsempty();
    int first_range_idx = -1, last_slot_idx = -1, i;
    for (i = 0; i < CLUSTER_MANAGER_SLOTS; i++) {
        int has_slot = node->slots[i];
        if (has_slot) {
            if (first_range_idx == -1) {
                if (sdslen(slots)) slots = sdscat(slots, ",");
                first_range_idx = i;
                slots = sdscatfmt(slots, "[%u", i);
            }
            last_slot_idx = i;
        } else {
            if (last_slot_idx >= 0) {
                if (first_range_idx == last_slot_idx)
                    slots = sdscat(slots, "]");
                else
                    slots = sdscatfmt(slots, "-%u]", last_slot_idx);
            }
            last_slot_idx = -1;
            first_range_idx = -1;
        }
    }
    if (last_slot_idx >= 0) {
        if (first_range_idx == last_slot_idx)
            slots = sdscat(slots, "]");
        else
            slots = sdscatfmt(slots, "-%u]", last_slot_idx);
    }
    return slots;
}

static sds clusterManagerNodeGetJSON(clusterManagerNode *node, unsigned long error_count) {
    sds json = sdsempty();
    sds replicate = sdsempty();
    if (node->replicate)
        replicate = sdscatprintf(replicate, "\"%s\"", node->replicate);
    else
        replicate = sdscat(replicate, "null");
    sds slots = clusterManagerNodeSlotsString(node);
    sds flags = clusterManagerNodeFlagString(node);
    char *p = slots;
    while ((p = strchr(p, '-')) != NULL) *(p++) = ',';
    json = sdscatprintf(json,
                        "  {\n"
                        "    \"name\": \"%s\",\n"
                        "    \"host\": \"%s\",\n"
                        "    \"port\": %d,\n"
                        "    \"replicate\": %s,\n"
                        "    \"slots\": [%s],\n"
                        "    \"slots_count\": %d,\n"
                        "    \"flags\": \"%s\",\n"
                        "    \"current_epoch\": %llu",
                        node->name, node->ip, node->port, replicate, slots, node->slots_count, flags,
                        (unsigned long long)node->current_epoch);
    if (error_count > 0) {
        json = sdscatprintf(json, ",\n    \"cluster_errors\": %lu", error_count);
    }
    if (node->migrating_count > 0 && node->migrating != NULL) {
        int i = 0;
        sds migrating = sdsempty();
        for (; i < node->migrating_count; i += 2) {
            sds slot = node->migrating[i];
            sds dest = node->migrating[i + 1];
            if (slot && dest) {
                if (sdslen(migrating) > 0) migrating = sdscat(migrating, ",");
                migrating = sdscatfmt(migrating, "\"%S\": \"%S\"", slot, dest);
            }
        }
        if (sdslen(migrating) > 0) json = sdscatfmt(json, ",\n    \"migrating\": {%S}", migrating);
        sdsfree(migrating);
    }
    if (node->importing_count > 0 && node->importing != NULL) {
        int i = 0;
        sds importing = sdsempty();
        for (; i < node->importing_count; i += 2) {
            sds slot = node->importing[i];
            sds from = node->importing[i + 1];
            if (slot && from) {
                if (sdslen(importing) > 0) importing = sdscat(importing, ",");
                importing = sdscatfmt(importing, "\"%S\": \"%S\"", slot, from);
            }
        }
        if (sdslen(importing) > 0) json = sdscatfmt(json, ",\n    \"importing\": {%S}", importing);
        sdsfree(importing);
    }
    json = sdscat(json, "\n  }");
    sdsfree(replicate);
    sdsfree(slots);
    sdsfree(flags);
    return json;
}


/* -----------------------------------------------------------------------------
 * Key space handling
 * -------------------------------------------------------------------------- */

/* We have 16384 hash slots. The hash slot of a given key is obtained
 * as the least significant 14 bits of the crc16 of the key.
 *
 * However if the key contains the {...} pattern, only the part between
 * { and } is hashed. This may be useful in the future to force certain
 * keys to be in the same node (assuming no resharding is in progress). */
static unsigned int clusterManagerKeyHashSlot(char *key, int keylen) {
    int s, e; /* start-end indexes of { and } */

    for (s = 0; s < keylen; s++)
        if (key[s] == '{') break;

    /* No '{' ? Hash the whole key. This is the base case. */
    if (s == keylen) return crc16(key, keylen) & 0x3FFF;

    /* '{' found? Check if we have the corresponding '}'. */
    for (e = s + 1; e < keylen; e++)
        if (key[e] == '}') break;

    /* No '}' or nothing between {} ? Hash the whole key. */
    if (e == keylen || e == s + 1) return crc16(key, keylen) & 0x3FFF;

    /* If we are here there is both a { and a } on its right. Hash
     * what is in the middle between { and }. */
    return crc16(key + s + 1, e - s - 1) & 0x3FFF;
}

/* Return a string representation of the cluster node. */
static sds clusterManagerNodeInfo(clusterManagerNode *node, int indent) {
    sds info = sdsempty();
    sds spaces = sdsempty();
    int i;
    for (i = 0; i < indent; i++) spaces = sdscat(spaces, " ");
    if (indent) info = sdscat(info, spaces);
    int is_primary = !(node->flags & CLUSTER_MANAGER_FLAG_REPLICA);
    char *role = (is_primary ? "M" : "S");
    sds slots = NULL;
    if (node->dirty && node->replicate != NULL)
        info = sdscatfmt(info, "S: %S %s:%u", node->name, node->ip, node->port);
    else {
        slots = clusterManagerNodeSlotsString(node);
        sds flags = clusterManagerNodeFlagString(node);
        info = sdscatfmt(info,
                         "%s: %S %s:%u\n"
                         "%s   slots:%S (%u slots) "
                         "%S",
                         role, node->name, node->ip, node->port, spaces, slots, node->slots_count, flags);
        sdsfree(slots);
        sdsfree(flags);
    }
    if (node->replicate != NULL)
        info = sdscatfmt(info, "\n%s   replicates %S", spaces, node->replicate);
    else if (node->replicas_count)
        info = sdscatfmt(info, "\n%s   %U additional replica(s)", spaces, node->replicas_count);
    sdsfree(spaces);
    return info;
}

static void clusterManagerShowNodes(void) {
    listIter li;
    listNode *ln;
    listRewind(cluster_manager.nodes, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *node = ln->value;
        sds info = clusterManagerNodeInfo(node, 0);
        printf("%s\n", (char *)info);
        sdsfree(info);
    }
}

static void clusterManagerShowClusterInfo(void) {
    int primaries = 0;
    long long keys = 0;
    listIter li;
    listNode *ln;
    listRewind(cluster_manager.nodes, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *node = ln->value;
        if (!(node->flags & CLUSTER_MANAGER_FLAG_REPLICA)) {
            if (!node->name) continue;
            int replicas = 0;
            long long dbsize = -1;
            char name[9];
            memcpy(name, node->name, 8);
            name[8] = '\0';
            listIter ri;
            listNode *rn;
            listRewind(cluster_manager.nodes, &ri);
            while ((rn = listNext(&ri)) != NULL) {
                clusterManagerNode *n = rn->value;
                if (n == node || !(n->flags & CLUSTER_MANAGER_FLAG_REPLICA)) continue;
                if (n->replicate && !strcmp(n->replicate, node->name)) replicas++;
            }
            redisReply *reply = CLUSTER_MANAGER_COMMAND(node, "DBSIZE");
            if (reply != NULL && reply->type == REDIS_REPLY_INTEGER) dbsize = reply->integer;
            if (dbsize < 0) {
                char *err = "";
                if (reply != NULL && reply->type == REDIS_REPLY_ERROR) err = reply->str;
                CLUSTER_MANAGER_PRINT_REPLY_ERROR(node, err);
                if (reply != NULL) freeReplyObject(reply);
                return;
            };
            if (reply != NULL) freeReplyObject(reply);
            printf("%s:%d (%s...) -> %lld keys | %d slots | %d replicas.\n", node->ip, node->port, name, dbsize,
                   node->slots_count, replicas);
            primaries++;
            keys += dbsize;
        }
    }
    clusterManagerLogOk("[OK] %lld keys in %d primaries.\n", keys, primaries);
    float keys_per_slot = keys / (float)CLUSTER_MANAGER_SLOTS;
    printf("%.2f keys per slot on average.\n", keys_per_slot);
}

/* Flush dirty slots configuration of the node by calling CLUSTER ADDSLOTS */
static int clusterManagerAddSlots(clusterManagerNode *node, char **err) {
    redisReply *reply = NULL;
    void *_reply = NULL;
    int success = 1;
    /* First two args are used for the command itself. */
    int argc = node->slots_count + 2;
    sds *argv = zmalloc(argc * sizeof(*argv));
    size_t *argvlen = zmalloc(argc * sizeof(*argvlen));
    argv[0] = "CLUSTER";
    argv[1] = "ADDSLOTS";
    argvlen[0] = 7;
    argvlen[1] = 8;
    *err = NULL;
    int i, argv_idx = 2;
    for (i = 0; i < CLUSTER_MANAGER_SLOTS; i++) {
        if (argv_idx >= argc) break;
        if (node->slots[i]) {
            argv[argv_idx] = sdsfromlonglong((long long)i);
            argvlen[argv_idx] = sdslen(argv[argv_idx]);
            argv_idx++;
        }
    }
    if (argv_idx == 2) {
        success = 0;
        goto cleanup;
    }
    redisAppendCommandArgv(node->context, argc, (const char **)argv, argvlen);
    if (redisGetReply(node->context, &_reply) != REDIS_OK) {
        success = 0;
        goto cleanup;
    }
    reply = (redisReply *)_reply;
    success = clusterManagerCheckRedisReply(node, reply, err);
cleanup:
    zfree(argvlen);
    if (argv != NULL) {
        for (i = 2; i < argc; i++) sdsfree(argv[i]);
        zfree(argv);
    }
    if (reply != NULL) freeReplyObject(reply);
    return success;
}

/* Get the node the slot is assigned to from the point of view of node *n.
 * If the slot is unassigned or if the reply is an error, return NULL.
 * Use the **err argument in order to check whether the slot is unassigned
 * or the reply resulted in an error. */
static clusterManagerNode *clusterManagerGetSlotOwner(clusterManagerNode *n, int slot, char **err) {
    assert(slot >= 0 && slot < CLUSTER_MANAGER_SLOTS);
    clusterManagerNode *owner = NULL;
    redisReply *reply = CLUSTER_MANAGER_COMMAND(n, "CLUSTER SLOTS");
    if (clusterManagerCheckRedisReply(n, reply, err)) {
        assert(reply->type == REDIS_REPLY_ARRAY);
        size_t i;
        for (i = 0; i < reply->elements; i++) {
            redisReply *r = reply->element[i];
            assert(r->type == REDIS_REPLY_ARRAY && r->elements >= 3);
            int from, to;
            from = r->element[0]->integer;
            to = r->element[1]->integer;
            if (slot < from || slot > to) continue;
            redisReply *nr = r->element[2];
            assert(nr->type == REDIS_REPLY_ARRAY && nr->elements >= 2);
            char *name = NULL;
            if (nr->elements >= 3) name = nr->element[2]->str;
            if (name != NULL)
                owner = clusterManagerNodeByName(name);
            else {
                char *ip = nr->element[0]->str;
                assert(ip != NULL);
                int port = (int)nr->element[1]->integer;
                listIter li;
                listNode *ln;
                listRewind(cluster_manager.nodes, &li);
                while ((ln = listNext(&li)) != NULL) {
                    clusterManagerNode *nd = ln->value;
                    if (strcmp(nd->ip, ip) == 0 && port == nd->port) {
                        owner = nd;
                        break;
                    }
                }
            }
            if (owner) break;
        }
    }
    if (reply) freeReplyObject(reply);
    return owner;
}

/* Set slot status to "importing" or "migrating" */
static int
clusterManagerSetSlot(clusterManagerNode *node1, clusterManagerNode *node2, int slot, const char *status, char **err) {
    redisReply *reply = CLUSTER_MANAGER_COMMAND(node1,
                                                "CLUSTER "
                                                "SETSLOT %d %s %s",
                                                slot, status, (char *)node2->name);
    if (err != NULL) *err = NULL;
    if (!reply) {
        if (err) *err = zstrdup("CLUSTER SETSLOT failed to run");
        return 0;
    }
    int success = 1;
    if (reply->type == REDIS_REPLY_ERROR) {
        success = 0;
        if (err != NULL) {
            *err = zmalloc((reply->len + 1) * sizeof(char));
            valkey_strlcpy(*err, reply->str, (reply->len + 1));
        } else
            CLUSTER_MANAGER_PRINT_REPLY_ERROR(node1, reply->str);
        goto cleanup;
    }
cleanup:
    freeReplyObject(reply);
    return success;
}

static int clusterManagerClearSlotStatus(clusterManagerNode *node, int slot) {
    redisReply *reply = CLUSTER_MANAGER_COMMAND(node, "CLUSTER SETSLOT %d %s", slot, "STABLE");
    int success = clusterManagerCheckRedisReply(node, reply, NULL);
    if (reply) freeReplyObject(reply);
    return success;
}

static int clusterManagerDelSlot(clusterManagerNode *node, int slot, int ignore_unassigned_err) {
    redisReply *reply = CLUSTER_MANAGER_COMMAND(node, "CLUSTER DELSLOTS %d", slot);
    char *err = NULL;
    int success = clusterManagerCheckRedisReply(node, reply, &err);
    if (!success && reply && reply->type == REDIS_REPLY_ERROR && ignore_unassigned_err) {
        char *get_owner_err = NULL;
        clusterManagerNode *assigned_to = clusterManagerGetSlotOwner(node, slot, &get_owner_err);
        if (!assigned_to) {
            if (get_owner_err == NULL)
                success = 1;
            else {
                CLUSTER_MANAGER_PRINT_REPLY_ERROR(node, get_owner_err);
                zfree(get_owner_err);
            }
        }
    }
    if (!success && err != NULL) {
        CLUSTER_MANAGER_PRINT_REPLY_ERROR(node, err);
        zfree(err);
    }
    if (reply) freeReplyObject(reply);
    return success;
}

static int clusterManagerAddSlot(clusterManagerNode *node, int slot) {
    redisReply *reply = CLUSTER_MANAGER_COMMAND(node, "CLUSTER ADDSLOTS %d", slot);
    int success = clusterManagerCheckRedisReply(node, reply, NULL);
    if (reply) freeReplyObject(reply);
    return success;
}

static signed int clusterManagerCountKeysInSlot(clusterManagerNode *node, int slot) {
    redisReply *reply = CLUSTER_MANAGER_COMMAND(node, "CLUSTER COUNTKEYSINSLOT %d", slot);
    int count = -1;
    int success = clusterManagerCheckRedisReply(node, reply, NULL);
    if (success && reply->type == REDIS_REPLY_INTEGER) count = reply->integer;
    if (reply) freeReplyObject(reply);
    return count;
}

static int clusterManagerBumpEpoch(clusterManagerNode *node) {
    redisReply *reply = CLUSTER_MANAGER_COMMAND(node, "CLUSTER BUMPEPOCH");
    int success = clusterManagerCheckRedisReply(node, reply, NULL);
    if (reply) freeReplyObject(reply);
    return success;
}

/* Callback used by clusterManagerSetSlotOwner transaction. It should ignore
 * errors except for ADDSLOTS errors.
 * Return 1 if the error should be ignored. */
static int clusterManagerOnSetOwnerErr(redisReply *reply, clusterManagerNode *n, int bulk_idx) {
    UNUSED(reply);
    UNUSED(n);
    /* Only raise error when ADDSLOTS fail (bulk_idx == 1). */
    return (bulk_idx != 1);
}

static int clusterManagerSetSlotOwner(clusterManagerNode *owner, int slot, int do_clear) {
    int success = clusterManagerStartTransaction(owner);
    if (!success) return 0;
    /* Ensure the slot is not already assigned. */
    clusterManagerDelSlot(owner, slot, 1);
    /* Add the slot and bump epoch. */
    clusterManagerAddSlot(owner, slot);
    if (do_clear) clusterManagerClearSlotStatus(owner, slot);
    clusterManagerBumpEpoch(owner);
    success = clusterManagerExecTransaction(owner, clusterManagerOnSetOwnerErr);
    return success;
}

/* Get the hash for the values of the specified keys in *keys_reply for the
 * specified nodes *n1 and *n2, by calling DEBUG DIGEST-VALUE command
 * on both nodes. Every key with same name on both nodes but having different
 * values will be added to the *diffs list. Return 0 in case of reply
 * error. */
static int
clusterManagerCompareKeysValues(clusterManagerNode *n1, clusterManagerNode *n2, redisReply *keys_reply, list *diffs) {
    size_t i, argc = keys_reply->elements + 2;
    static const char *hash_zero = "0000000000000000000000000000000000000000";
    char **argv = zcalloc(argc * sizeof(char *));
    size_t *argv_len = zcalloc(argc * sizeof(size_t));
    argv[0] = "DEBUG";
    argv_len[0] = 5;
    argv[1] = "DIGEST-VALUE";
    argv_len[1] = 12;
    for (i = 0; i < keys_reply->elements; i++) {
        redisReply *entry = keys_reply->element[i];
        int idx = i + 2;
        argv[idx] = entry->str;
        argv_len[idx] = entry->len;
    }
    int success = 0;
    void *_reply1 = NULL, *_reply2 = NULL;
    redisReply *r1 = NULL, *r2 = NULL;
    redisAppendCommandArgv(n1->context, argc, (const char **)argv, argv_len);
    success = (redisGetReply(n1->context, &_reply1) == REDIS_OK);
    if (!success) goto cleanup;
    r1 = (redisReply *)_reply1;
    redisAppendCommandArgv(n2->context, argc, (const char **)argv, argv_len);
    success = (redisGetReply(n2->context, &_reply2) == REDIS_OK);
    if (!success) goto cleanup;
    r2 = (redisReply *)_reply2;
    success = (r1->type != REDIS_REPLY_ERROR && r2->type != REDIS_REPLY_ERROR);
    if (r1->type == REDIS_REPLY_ERROR) {
        CLUSTER_MANAGER_PRINT_REPLY_ERROR(n1, r1->str);
        success = 0;
    }
    if (r2->type == REDIS_REPLY_ERROR) {
        CLUSTER_MANAGER_PRINT_REPLY_ERROR(n2, r2->str);
        success = 0;
    }
    if (!success) goto cleanup;
    assert(keys_reply->elements == r1->elements && keys_reply->elements == r2->elements);
    for (i = 0; i < keys_reply->elements; i++) {
        char *key = keys_reply->element[i]->str;
        char *hash1 = r1->element[i]->str;
        char *hash2 = r2->element[i]->str;
        /* Ignore keys that don't exist in both nodes. */
        if (strcmp(hash1, hash_zero) == 0 || strcmp(hash2, hash_zero) == 0) continue;
        if (strcmp(hash1, hash2) != 0) listAddNodeTail(diffs, key);
    }
cleanup:
    if (r1) freeReplyObject(r1);
    if (r2) freeReplyObject(r2);
    zfree(argv);
    zfree(argv_len);
    return success;
}

/* Migrate keys taken from reply->elements. It returns the reply from the
 * MIGRATE command, or NULL if something goes wrong. If the argument 'dots'
 * is not NULL, a dot will be printed for every migrated key. */
static redisReply *clusterManagerMigrateKeysInReply(clusterManagerNode *source,
                                                    clusterManagerNode *target,
                                                    redisReply *reply,
                                                    int replace,
                                                    int timeout,
                                                    char *dots) {
    redisReply *migrate_reply = NULL;
    char **argv = NULL;
    size_t *argv_len = NULL;
    int c = (replace ? 8 : 7);
    if (config.conn_info.auth) c += 2;
    if (config.conn_info.user) c += 1;
    size_t argc = c + reply->elements;
    size_t i, offset = 6; // Keys Offset
    argv = zcalloc(argc * sizeof(char *));
    argv_len = zcalloc(argc * sizeof(size_t));
    char portstr[255];
    char timeoutstr[255];
    snprintf(portstr, 10, "%d", target->port);
    snprintf(timeoutstr, 10, "%d", timeout);
    argv[0] = "MIGRATE";
    argv_len[0] = 7;
    argv[1] = target->ip;
    argv_len[1] = strlen(target->ip);
    argv[2] = portstr;
    argv_len[2] = strlen(portstr);
    argv[3] = "";
    argv_len[3] = 0;
    argv[4] = "0";
    argv_len[4] = 1;
    argv[5] = timeoutstr;
    argv_len[5] = strlen(timeoutstr);
    if (replace) {
        argv[offset] = "REPLACE";
        argv_len[offset] = 7;
        offset++;
    }
    if (config.conn_info.auth) {
        if (config.conn_info.user) {
            argv[offset] = "AUTH2";
            argv_len[offset] = 5;
            offset++;
            argv[offset] = config.conn_info.user;
            argv_len[offset] = strlen(config.conn_info.user);
            offset++;
            argv[offset] = config.conn_info.auth;
            argv_len[offset] = strlen(config.conn_info.auth);
            offset++;
        } else {
            argv[offset] = "AUTH";
            argv_len[offset] = 4;
            offset++;
            argv[offset] = config.conn_info.auth;
            argv_len[offset] = strlen(config.conn_info.auth);
            offset++;
        }
    }
    argv[offset] = "KEYS";
    argv_len[offset] = 4;
    offset++;
    for (i = 0; i < reply->elements; i++) {
        redisReply *entry = reply->element[i];
        size_t idx = i + offset;
        assert(entry->type == REDIS_REPLY_STRING);
        argv[idx] = (char *)sdsnewlen(entry->str, entry->len);
        argv_len[idx] = entry->len;
        if (dots) dots[i] = '.';
    }
    if (dots) dots[reply->elements] = '\0';
    void *_reply = NULL;
    redisAppendCommandArgv(source->context, argc, (const char **)argv, argv_len);
    int success = (redisGetReply(source->context, &_reply) == REDIS_OK);
    for (i = 0; i < reply->elements; i++) sdsfree(argv[i + offset]);
    if (!success) goto cleanup;
    migrate_reply = (redisReply *)_reply;
cleanup:
    zfree(argv);
    zfree(argv_len);
    return migrate_reply;
}

/* Migrate all keys in the given slot from source to target.*/
static int clusterManagerMigrateKeysInSlot(clusterManagerNode *source,
                                           clusterManagerNode *target,
                                           int slot,
                                           int timeout,
                                           int pipeline,
                                           int verbose,
                                           char **err) {
    int success = 1;
    int do_fix = config.cluster_manager_command.flags & CLUSTER_MANAGER_CMD_FLAG_FIX;
    int do_replace = config.cluster_manager_command.flags & CLUSTER_MANAGER_CMD_FLAG_REPLACE;
    while (1) {
        char *dots = NULL;
        redisReply *reply = NULL, *migrate_reply = NULL;
        reply = CLUSTER_MANAGER_COMMAND(source,
                                        "CLUSTER "
                                        "GETKEYSINSLOT %d %d",
                                        slot, pipeline);
        success = (reply != NULL);
        if (!success) return 0;
        if (reply->type == REDIS_REPLY_ERROR) {
            success = 0;
            if (err != NULL) {
                *err = zmalloc((reply->len + 1) * sizeof(char));
                valkey_strlcpy(*err, reply->str, (reply->len + 1));
                CLUSTER_MANAGER_PRINT_REPLY_ERROR(source, *err);
            }
            goto next;
        }
        assert(reply->type == REDIS_REPLY_ARRAY);
        size_t count = reply->elements;
        if (count == 0) {
            freeReplyObject(reply);
            break;
        }
        if (verbose) dots = zmalloc((count + 1) * sizeof(char));
        /* Calling MIGRATE command. */
        migrate_reply = clusterManagerMigrateKeysInReply(source, target, reply, 0, timeout, dots);
        if (migrate_reply == NULL) goto next;
        if (migrate_reply->type == REDIS_REPLY_ERROR) {
            int is_busy = strstr(migrate_reply->str, "BUSYKEY") != NULL;
            int not_served = 0;
            if (!is_busy) {
                /* Check if the slot is unassigned (not served) in the
                 * source node's configuration. */
                char *get_owner_err = NULL;
                clusterManagerNode *served_by = clusterManagerGetSlotOwner(source, slot, &get_owner_err);
                if (!served_by) {
                    if (get_owner_err == NULL)
                        not_served = 1;
                    else {
                        CLUSTER_MANAGER_PRINT_REPLY_ERROR(source, get_owner_err);
                        zfree(get_owner_err);
                    }
                }
            }
            /* Try to handle errors. */
            if (is_busy || not_served) {
                /* If the key's slot is not served, try to assign slot
                 * to the target node. */
                if (do_fix && not_served) {
                    clusterManagerLogWarn("*** Slot was not served, setting "
                                          "owner to node %s:%d.\n",
                                          target->ip, target->port);
                    clusterManagerSetSlot(source, target, slot, "node", NULL);
                }
                /* If the key already exists in the target node (BUSYKEY),
                 * check whether its value is the same in both nodes.
                 * In case of equal values, retry migration with the
                 * REPLACE option.
                 *
                 * In case of different values:
                 *  - If --cluster-replace option is not provided, stop
                 *    and warn the user.
                 *  - If --cluster-replace option is provided, proceed it. */
                if (is_busy) {
                    clusterManagerLogWarn("\n*** Target key exists\n");
                    if (!do_replace) {
                        clusterManagerLogWarn("*** Checking key values on "
                                              "both nodes...\n");
                        list *diffs = listCreate();
                        success = clusterManagerCompareKeysValues(source, target, reply, diffs);
                        if (!success) {
                            clusterManagerLogErr("*** Value check failed!\n");
                            listRelease(diffs);
                            goto next;
                        }
                        if (listLength(diffs) > 0) {
                            success = 0;
                            clusterManagerLogErr("*** Found %d key(s) in both source node and "
                                                 "target node having different values.\n"
                                                 "    Source node: %s:%d\n"
                                                 "    Target node: %s:%d\n"
                                                 "    Keys(s):\n",
                                                 listLength(diffs), source->ip, source->port, target->ip, target->port);
                            listIter dli;
                            listNode *dln;
                            listRewind(diffs, &dli);
                            while ((dln = listNext(&dli)) != NULL) {
                                char *k = dln->value;
                                clusterManagerLogErr("    - %s\n", k);
                            }
                            clusterManagerLogErr("Please fix the above key(s) "
                                                 "manually and try again "
                                                 "or relaunch the command \n"
                                                 "with --cluster-replace "
                                                 "option to force key "
                                                 "overriding.\n");
                            listRelease(diffs);
                            goto next;
                        }
                        listRelease(diffs);
                    }
                    clusterManagerLogWarn("*** Replacing target keys...\n");
                }
                freeReplyObject(migrate_reply);
                migrate_reply = clusterManagerMigrateKeysInReply(source, target, reply, is_busy, timeout, NULL);
                success = (migrate_reply != NULL && migrate_reply->type != REDIS_REPLY_ERROR);
            } else
                success = 0;
            if (!success) {
                if (migrate_reply != NULL) {
                    if (err) {
                        *err = zmalloc((migrate_reply->len + 1) * sizeof(char));
                        valkey_strlcpy(*err, migrate_reply->str, (migrate_reply->len + 1));
                    }
                    printf("\n");
                    CLUSTER_MANAGER_PRINT_REPLY_ERROR(source, migrate_reply->str);
                }
                goto next;
            }
        }
        if (verbose) {
            printf("%s", dots);
            fflush(stdout);
        }
    next:
        if (reply != NULL) freeReplyObject(reply);
        if (migrate_reply != NULL) freeReplyObject(migrate_reply);
        if (dots) zfree(dots);
        if (!success) break;
    }
    return success;
}

/* Move slots between source and target nodes using MIGRATE.
 *
 * Options:
 * CLUSTER_MANAGER_OPT_VERBOSE -- Print a dot for every moved key.
 * CLUSTER_MANAGER_OPT_COLD    -- Move keys without opening slots /
 *                                reconfiguring the nodes.
 * CLUSTER_MANAGER_OPT_UPDATE  -- Update node->slots for source/target nodes.
 * CLUSTER_MANAGER_OPT_QUIET   -- Don't print info messages.
 */
static int
clusterManagerMoveSlot(clusterManagerNode *source, clusterManagerNode *target, int slot, int opts, char **err) {
    if (!(opts & CLUSTER_MANAGER_OPT_QUIET)) {
        printf("Moving slot %d from %s:%d to %s:%d: ", slot, source->ip, source->port, target->ip, target->port);
        fflush(stdout);
    }
    if (err != NULL) *err = NULL;
    int pipeline = config.cluster_manager_command.pipeline, timeout = config.cluster_manager_command.timeout,
        print_dots = (opts & CLUSTER_MANAGER_OPT_VERBOSE), option_cold = (opts & CLUSTER_MANAGER_OPT_COLD), success = 1;
    if (!option_cold) {
        success = clusterManagerSetSlot(target, source, slot, "importing", err);
        if (!success) return 0;
        success = clusterManagerSetSlot(source, target, slot, "migrating", err);
        if (!success) return 0;
    }
    success = clusterManagerMigrateKeysInSlot(source, target, slot, timeout, pipeline, print_dots, err);
    if (!(opts & CLUSTER_MANAGER_OPT_QUIET)) printf("\n");
    if (!success) return 0;
    if (!option_cold) {
        /* Set the new node as the owner of the slot in all the known nodes.
         *
         * We inform the target node first. It will propagate the information to
         * the rest of the cluster.
         *
         * If we inform any other node first, it can happen that the target node
         * crashes before it is set as the new owner and then the slot is left
         * without an owner which results in redirect loops. See issue #7116. */
        success = clusterManagerSetSlot(target, target, slot, "node", err);
        if (!success) return 0;

        /* Inform the source node. If the source node has just lost its last
         * slot and the target node has already informed the source node, the
         * source node has turned itself into a replica. This is not an error in
         * this scenario so we ignore it. See issue #9223.
         *
         * Another acceptable error can arise now that the primary pre-replicates
         * `cluster setslot` commands to replicas while blocking the client on the
         * primary. This change enhances the reliability of `cluster setslot` in
         * the face of primary failures. However, while our client is blocked on
         * the primary awaiting replication, the primary might become a replica
         * for the same reason as mentioned above, resulting in the client being
         * unblocked with the role change error. */
        success = clusterManagerSetSlot(source, target, slot, "node", err);
        if (!success && err) {
            const char *acceptable[] = {"ERR Please use SETSLOT only with masters.",
                                        "ERR Please use SETSLOT only with primaries.", "UNBLOCKED"};
            for (size_t i = 0; i < sizeof(acceptable) / sizeof(acceptable[0]); i++) {
                if (!strncmp(*err, acceptable[i], strlen(acceptable[i]))) {
                    zfree(*err);
                    *err = NULL;
                    success = 1;
                    break;
                }
            }
        }
        if (!success && err) {
            return 0;
        }

        /* We also inform the other nodes to avoid redirects in case the target
         * node is slow to propagate the change to the entire cluster. */
        listIter li;
        listNode *ln;
        listRewind(cluster_manager.nodes, &li);
        while ((ln = listNext(&li)) != NULL) {
            clusterManagerNode *n = ln->value;
            if (n == target || n == source) continue; /* already done */
            if (n->flags & CLUSTER_MANAGER_FLAG_REPLICA) continue;
            success = clusterManagerSetSlot(n, target, slot, "node", err);
            if (!success) return 0;
        }
    }
    /* Update the node logical config */
    if (opts & CLUSTER_MANAGER_OPT_UPDATE) {
        source->slots[slot] = 0;
        target->slots[slot] = 1;
    }
    return 1;
}

/* Flush the dirty node configuration by calling replicate for replicas or
 * adding the slots defined in the primaries. */
static int clusterManagerFlushNodeConfig(clusterManagerNode *node, char **err) {
    if (!node->dirty) return 0;
    redisReply *reply = NULL;
    int is_err = 0, success = 1;
    if (err != NULL) *err = NULL;
    if (node->replicate != NULL) {
        reply = CLUSTER_MANAGER_COMMAND(node, "CLUSTER REPLICATE %s", node->replicate);
        if (reply == NULL || (is_err = (reply->type == REDIS_REPLY_ERROR))) {
            if (is_err && err != NULL) {
                *err = zmalloc((reply->len + 1) * sizeof(char));
                valkey_strlcpy(*err, reply->str, (reply->len + 1));
            }
            success = 0;
            /* If the cluster did not already joined it is possible that
             * the replica does not know the primary node yet. So on errors
             * we return ASAP leaving the dirty flag set, to flush the
             * config later. */
            goto cleanup;
        }
    } else {
        int added = clusterManagerAddSlots(node, err);
        if (!added || *err != NULL) success = 0;
    }
    node->dirty = 0;
cleanup:
    if (reply != NULL) freeReplyObject(reply);
    return success;
}

/* Wait until the cluster configuration is consistent. */
static void clusterManagerWaitForClusterJoin(void) {
    printf("Waiting for the cluster to join\n");
    int counter = 0, check_after = CLUSTER_JOIN_CHECK_AFTER + (int)(listLength(cluster_manager.nodes) * 0.15f);
    while (!clusterManagerIsConfigConsistent()) {
        printf(".");
        fflush(stdout);
        sleep(1);
        if (++counter > check_after) {
            dict *status = clusterManagerGetLinkStatus();
            dictIterator *iter = NULL;
            if (status != NULL && dictSize(status) > 0) {
                printf("\n");
                clusterManagerLogErr("Warning: %d node(s) may "
                                     "be unreachable\n",
                                     dictSize(status));
                iter = dictGetIterator(status);
                dictEntry *entry;
                while ((entry = dictNext(iter)) != NULL) {
                    sds nodeaddr = (sds)dictGetKey(entry);
                    char *node_ip = NULL;
                    int node_port = 0, node_bus_port = 0;
                    list *from = (list *)dictGetVal(entry);
                    if (parseClusterNodeAddress(nodeaddr, &node_ip, &node_port, &node_bus_port) && node_bus_port) {
                        clusterManagerLogErr(" - The port %d of node %s may "
                                             "be unreachable from:\n",
                                             node_bus_port, node_ip);
                    } else {
                        clusterManagerLogErr(" - Node %s may be unreachable "
                                             "from:\n",
                                             nodeaddr);
                    }
                    listIter li;
                    listNode *ln;
                    listRewind(from, &li);
                    while ((ln = listNext(&li)) != NULL) {
                        sds from_addr = ln->value;
                        clusterManagerLogErr("   %s\n", from_addr);
                        sdsfree(from_addr);
                    }
                    clusterManagerLogErr("Cluster bus ports must be reachable "
                                         "by every node.\nRemember that "
                                         "cluster bus ports are different "
                                         "from standard instance ports.\n");
                    listEmpty(from);
                }
            }
            if (iter != NULL) dictReleaseIterator(iter);
            if (status != NULL) dictRelease(status);
            counter = 0;
        }
    }
    printf("\n");
}

/* Load node's cluster configuration by calling "CLUSTER NODES" command.
 * Node's configuration (name, replicate, slots, ...) is then updated.
 * If CLUSTER_MANAGER_OPT_GETFRIENDS flag is set into 'opts' argument,
 * and node already knows other nodes, the node's friends list is populated
 * with the other nodes info. */
static int clusterManagerNodeLoadInfo(clusterManagerNode *node, int opts, char **err) {
    redisReply *reply = CLUSTER_MANAGER_COMMAND(node, "CLUSTER NODES");
    int success = 1;
    *err = NULL;
    if (!clusterManagerCheckRedisReply(node, reply, err)) {
        success = 0;
        goto cleanup;
    }
    int getfriends = (opts & CLUSTER_MANAGER_OPT_GETFRIENDS);
    char *lines = reply->str, *p, *line;
    while ((p = strstr(lines, "\n")) != NULL) {
        *p = '\0';
        line = lines;
        lines = p + 1;
        char *name = NULL, *addr = NULL, *flags = NULL, *primary_id = NULL, *ping_sent = NULL, *ping_recv = NULL,
             *config_epoch = NULL, *link_status = NULL;
        UNUSED(link_status);
        int i = 0;
        while ((p = strchr(line, ' ')) != NULL) {
            *p = '\0';
            char *token = line;
            line = p + 1;
            switch (i++) {
            case 0: name = token; break;
            case 1: addr = token; break;
            case 2: flags = token; break;
            case 3: primary_id = token; break;
            case 4: ping_sent = token; break;
            case 5: ping_recv = token; break;
            case 6: config_epoch = token; break;
            case 7: link_status = token; break;
            }
            if (i == 8) break; // Slots
        }
        if (!flags) {
            success = 0;
            goto cleanup;
        }

        char *ip = NULL;
        int port = 0, bus_port = 0;
        if (addr == NULL || !parseClusterNodeAddress(addr, &ip, &port, &bus_port)) {
            fprintf(stderr, "Error: invalid CLUSTER NODES reply\n");
            success = 0;
            goto cleanup;
        }

        int myself = (strstr(flags, "myself") != NULL);
        clusterManagerNode *currentNode = NULL;
        if (myself) {
            /* bus-port could be wrong, correct it here, see clusterManagerNewNode. */
            node->bus_port = bus_port;
            node->flags |= CLUSTER_MANAGER_FLAG_MYSELF;
            currentNode = node;
            clusterManagerNodeResetSlots(node);
            if (i == 8) {
                int remaining = strlen(line);
                while (remaining > 0) {
                    p = strchr(line, ' ');
                    if (p == NULL) p = line + remaining;
                    remaining -= (p - line);

                    char *slotsdef = line;
                    *p = '\0';
                    if (remaining) {
                        line = p + 1;
                        remaining--;
                    } else
                        line = p;
                    char *dash = NULL;
                    if (slotsdef[0] == '[') {
                        slotsdef++;
                        if ((p = strstr(slotsdef, "->-"))) { // Migrating
                            *p = '\0';
                            p += 3;
                            char *closing_bracket = strchr(p, ']');
                            if (closing_bracket) *closing_bracket = '\0';
                            sds slot = sdsnew(slotsdef);
                            sds dst = sdsnew(p);
                            node->migrating_count += 2;
                            node->migrating = zrealloc(node->migrating, (node->migrating_count * sizeof(sds)));
                            node->migrating[node->migrating_count - 2] = slot;
                            node->migrating[node->migrating_count - 1] = dst;
                        } else if ((p = strstr(slotsdef, "-<-"))) { // Importing
                            *p = '\0';
                            p += 3;
                            char *closing_bracket = strchr(p, ']');
                            if (closing_bracket) *closing_bracket = '\0';
                            sds slot = sdsnew(slotsdef);
                            sds src = sdsnew(p);
                            node->importing_count += 2;
                            node->importing = zrealloc(node->importing, (node->importing_count * sizeof(sds)));
                            node->importing[node->importing_count - 2] = slot;
                            node->importing[node->importing_count - 1] = src;
                        }
                    } else if ((dash = strchr(slotsdef, '-')) != NULL) {
                        p = dash;
                        int start, stop;
                        *p = '\0';
                        start = atoi(slotsdef);
                        stop = atoi(p + 1);
                        node->slots_count += (stop - (start - 1));
                        while (start <= stop) node->slots[start++] = 1;
                    } else if (p > slotsdef) {
                        node->slots[atoi(slotsdef)] = 1;
                        node->slots_count++;
                    }
                }
            }
            node->dirty = 0;
        } else if (!getfriends) {
            if (!(node->flags & CLUSTER_MANAGER_FLAG_MYSELF))
                continue;
            else
                break;
        } else {
            currentNode = clusterManagerNewNode(sdsnew(ip), port, bus_port);
            currentNode->flags |= CLUSTER_MANAGER_FLAG_FRIEND;
            if (node->friends == NULL) node->friends = listCreate();
            listAddNodeTail(node->friends, currentNode);
        }
        if (name != NULL) {
            if (currentNode->name) sdsfree(currentNode->name);
            currentNode->name = sdsnew(name);
        }
        if (currentNode->flags_str != NULL) freeClusterManagerNodeFlags(currentNode->flags_str);
        currentNode->flags_str = listCreate();
        int flag_len;
        while ((flag_len = strlen(flags)) > 0) {
            sds flag = NULL;
            char *fp = strchr(flags, ',');
            if (fp) {
                *fp = '\0';
                flag = sdsnew(flags);
                flags = fp + 1;
            } else {
                flag = sdsnew(flags);
                flags += flag_len;
            }
            if (strcmp(flag, "noaddr") == 0)
                currentNode->flags |= CLUSTER_MANAGER_FLAG_NOADDR;
            else if (strcmp(flag, "disconnected") == 0)
                currentNode->flags |= CLUSTER_MANAGER_FLAG_DISCONNECT;
            else if (strcmp(flag, "fail") == 0)
                currentNode->flags |= CLUSTER_MANAGER_FLAG_FAIL;
            else if ((strcmp(flag, "slave") == 0) || (strcmp(flag, "replica") == 0)) {
                currentNode->flags |= CLUSTER_MANAGER_FLAG_REPLICA;
                if (primary_id != NULL) {
                    if (currentNode->replicate) sdsfree(currentNode->replicate);
                    currentNode->replicate = sdsnew(primary_id);
                }
            }
            listAddNodeTail(currentNode->flags_str, flag);
        }
        if (config_epoch != NULL) currentNode->current_epoch = atoll(config_epoch);
        if (ping_sent != NULL) currentNode->ping_sent = atoll(ping_sent);
        if (ping_recv != NULL) currentNode->ping_recv = atoll(ping_recv);
        if (!getfriends && myself) break;
    }
cleanup:
    if (reply) freeReplyObject(reply);
    return success;
}

/* Retrieves info about the cluster using argument 'node' as the starting
 * point. All nodes will be loaded inside the cluster_manager.nodes list.
 * Warning: if something goes wrong, it will free the starting node before
 * returning 0. */
static int clusterManagerLoadInfoFromNode(clusterManagerNode *node) {
    if (node->context == NULL && !clusterManagerNodeConnect(node)) {
        freeClusterManagerNode(node);
        return 0;
    }
    char *e = NULL;
    if (!clusterManagerNodeIsCluster(node, &e)) {
        clusterManagerPrintNotClusterNodeError(node, e);
        if (e) zfree(e);
        freeClusterManagerNode(node);
        return 0;
    }
    e = NULL;
    if (!clusterManagerNodeLoadInfo(node, CLUSTER_MANAGER_OPT_GETFRIENDS, &e)) {
        if (e) {
            CLUSTER_MANAGER_PRINT_REPLY_ERROR(node, e);
            zfree(e);
        }
        freeClusterManagerNode(node);
        return 0;
    }
    listIter li;
    listNode *ln;
    if (cluster_manager.nodes != NULL) {
        listRewind(cluster_manager.nodes, &li);
        while ((ln = listNext(&li)) != NULL) freeClusterManagerNode((clusterManagerNode *)ln->value);
        listRelease(cluster_manager.nodes);
    }
    cluster_manager.nodes = listCreate();
    listAddNodeTail(cluster_manager.nodes, node);
    if (node->friends != NULL) {
        listRewind(node->friends, &li);
        while ((ln = listNext(&li)) != NULL) {
            clusterManagerNode *friend = ln->value;
            if (!friend->ip || !friend->port) goto invalid_friend;
            if (!friend->context && !clusterManagerNodeConnect(friend)) goto invalid_friend;
            e = NULL;
            if (clusterManagerNodeLoadInfo(friend, 0, &e)) {
                if (friend->flags &
                    (CLUSTER_MANAGER_FLAG_NOADDR | CLUSTER_MANAGER_FLAG_DISCONNECT | CLUSTER_MANAGER_FLAG_FAIL)) {
                    goto invalid_friend;
                }
                listAddNodeTail(cluster_manager.nodes, friend);
            } else {
                clusterManagerLogErr("[ERR] Unable to load info for "
                                     "node %s:%d\n",
                                     friend->ip, friend->port);
                goto invalid_friend;
            }
            continue;
        invalid_friend:
            if (!(friend->flags & CLUSTER_MANAGER_FLAG_REPLICA)) cluster_manager.unreachable_primaries++;
            freeClusterManagerNode(friend);
        }
        listRelease(node->friends);
        node->friends = NULL;
    }
    // Count replicas for each node
    listRewind(cluster_manager.nodes, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *n = ln->value;
        if (n->replicate != NULL) {
            clusterManagerNode *primary = clusterManagerNodeByName(n->replicate);
            if (primary == NULL) {
                clusterManagerLogWarn("*** WARNING: %s:%d claims to be "
                                      "replica of unknown node ID %s.\n",
                                      n->ip, n->port, n->replicate);
            } else
                primary->replicas_count++;
        }
    }
    return 1;
}

/* Compare functions used by various sorting operations. */
int clusterManagerSlotCompare(const void *slot1, const void *slot2) {
    const char **i1 = (const char **)slot1;
    const char **i2 = (const char **)slot2;
    return strcmp(*i1, *i2);
}

int clusterManagerSlotCountCompareDesc(const void *n1, const void *n2) {
    clusterManagerNode *node1 = *((clusterManagerNode **)n1);
    clusterManagerNode *node2 = *((clusterManagerNode **)n2);
    return node2->slots_count - node1->slots_count;
}

int clusterManagerCompareNodeBalance(const void *n1, const void *n2) {
    clusterManagerNode *node1 = *((clusterManagerNode **)n1);
    clusterManagerNode *node2 = *((clusterManagerNode **)n2);
    return node1->balance - node2->balance;
}

static sds clusterManagerGetConfigSignature(clusterManagerNode *node) {
    sds signature = NULL;
    int node_count = 0, i = 0, name_len = 0;
    char **node_configs = NULL;
    redisReply *reply = CLUSTER_MANAGER_COMMAND(node, "CLUSTER NODES");
    if (reply == NULL || reply->type == REDIS_REPLY_ERROR) goto cleanup;
    char *lines = reply->str, *p, *line;
    while ((p = strstr(lines, "\n")) != NULL) {
        i = 0;
        *p = '\0';
        line = lines;
        lines = p + 1;
        char *nodename = NULL;
        int tot_size = 0;
        while ((p = strchr(line, ' ')) != NULL) {
            *p = '\0';
            char *token = line;
            line = p + 1;
            if (i == 0) {
                nodename = token;
                tot_size = (p - token);
                name_len = tot_size++; // Make room for ':' in tot_size
            }
            if (++i == 8) break;
        }
        if (i != 8) continue;
        if (nodename == NULL) continue;
        int remaining = strlen(line);
        if (remaining == 0) continue;
        char **slots = NULL;
        int c = 0;
        while (remaining > 0) {
            p = strchr(line, ' ');
            if (p == NULL) p = line + remaining;
            int size = (p - line);
            remaining -= size;
            tot_size += size;
            char *slotsdef = line;
            *p = '\0';
            if (remaining) {
                line = p + 1;
                remaining--;
            } else
                line = p;
            if (slotsdef[0] != '[') {
                c++;
                slots = zrealloc(slots, (c * sizeof(char *)));
                slots[c - 1] = slotsdef;
            }
        }
        if (c > 0) {
            if (c > 1) qsort(slots, c, sizeof(char *), clusterManagerSlotCompare);
            node_count++;
            node_configs = zrealloc(node_configs, (node_count * sizeof(char *)));
            /* Make room for '|' separators. */
            tot_size += (sizeof(char) * (c - 1));
            char *cfg = zmalloc((sizeof(char) * tot_size) + 1);
            memcpy(cfg, nodename, name_len);
            char *sp = cfg + name_len;
            *(sp++) = ':';
            for (i = 0; i < c; i++) {
                if (i > 0) *(sp++) = ',';
                int slen = strlen(slots[i]);
                memcpy(sp, slots[i], slen);
                sp += slen;
            }
            *(sp++) = '\0';
            node_configs[node_count - 1] = cfg;
        }
        zfree(slots);
    }
    if (node_count > 0) {
        if (node_count > 1) {
            qsort(node_configs, node_count, sizeof(char *), clusterManagerSlotCompare);
        }
        signature = sdsempty();
        for (i = 0; i < node_count; i++) {
            if (i > 0) signature = sdscatprintf(signature, "%c", '|');
            signature = sdscatfmt(signature, "%s", node_configs[i]);
        }
    }
cleanup:
    if (reply != NULL) freeReplyObject(reply);
    if (node_configs != NULL) {
        for (i = 0; i < node_count; i++) zfree(node_configs[i]);
        zfree(node_configs);
    }
    return signature;
}

static int clusterManagerIsConfigConsistent(void) {
    if (cluster_manager.nodes == NULL) return 0;
    int consistent = (listLength(cluster_manager.nodes) <= 1);
    // If the Cluster has only one node, it's always consistent
    if (consistent) return 1;
    sds first_cfg = NULL;
    listIter li;
    listNode *ln;
    listRewind(cluster_manager.nodes, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *node = ln->value;
        sds cfg = clusterManagerGetConfigSignature(node);
        if (cfg == NULL) {
            consistent = 0;
            break;
        }
        if (first_cfg == NULL)
            first_cfg = cfg;
        else {
            consistent = !sdscmp(first_cfg, cfg);
            sdsfree(cfg);
            if (!consistent) break;
        }
    }
    if (first_cfg != NULL) sdsfree(first_cfg);
    return consistent;
}

static list *clusterManagerGetDisconnectedLinks(clusterManagerNode *node) {
    list *links = NULL;
    redisReply *reply = CLUSTER_MANAGER_COMMAND(node, "CLUSTER NODES");
    if (!clusterManagerCheckRedisReply(node, reply, NULL)) goto cleanup;
    links = listCreate();
    char *lines = reply->str, *p, *line;
    while ((p = strstr(lines, "\n")) != NULL) {
        int i = 0;
        *p = '\0';
        line = lines;
        lines = p + 1;
        char *nodename = NULL, *addr = NULL, *flags = NULL, *link_status = NULL;
        while ((p = strchr(line, ' ')) != NULL) {
            *p = '\0';
            char *token = line;
            line = p + 1;
            if (i == 0)
                nodename = token;
            else if (i == 1)
                addr = token;
            else if (i == 2)
                flags = token;
            else if (i == 7)
                link_status = token;
            else if (i == 8)
                break;
            i++;
        }
        if (i == 7) link_status = line;
        if (nodename == NULL || addr == NULL || flags == NULL || link_status == NULL) continue;
        if (strstr(flags, "myself") != NULL) continue;
        int disconnected = ((strstr(flags, "disconnected") != NULL) || (strstr(link_status, "disconnected")));
        int handshaking = (strstr(flags, "handshake") != NULL);
        if (disconnected || handshaking) {
            clusterManagerLink *link = zmalloc(sizeof(*link));
            link->node_name = sdsnew(nodename);
            link->node_addr = sdsnew(addr);
            link->connected = 0;
            link->handshaking = handshaking;
            listAddNodeTail(links, link);
        }
    }
cleanup:
    if (reply != NULL) freeReplyObject(reply);
    return links;
}

/* Check for disconnected cluster links. It returns a dict whose keys
 * are the unreachable node addresses and the values are lists of
 * node addresses that cannot reach the unreachable node. */
static dict *clusterManagerGetLinkStatus(void) {
    if (cluster_manager.nodes == NULL) return NULL;
    dict *status = dictCreate(&clusterManagerLinkDictType);
    listIter li;
    listNode *ln;
    listRewind(cluster_manager.nodes, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *node = ln->value;
        list *links = clusterManagerGetDisconnectedLinks(node);
        if (links) {
            listIter lli;
            listNode *lln;
            listRewind(links, &lli);
            while ((lln = listNext(&lli)) != NULL) {
                clusterManagerLink *link = lln->value;
                list *from = NULL;
                dictEntry *entry = dictFind(status, link->node_addr);
                if (entry)
                    from = dictGetVal(entry);
                else {
                    from = listCreate();
                    dictAdd(status, sdsdup(link->node_addr), from);
                }
                sds myaddr = sdsempty();
                myaddr = sdscatfmt(myaddr, "%s:%u", node->ip, node->port);
                listAddNodeTail(from, myaddr);
                sdsfree(link->node_name);
                sdsfree(link->node_addr);
                zfree(link);
            }
            listRelease(links);
        }
    }
    return status;
}

/* Add the error string to cluster_manager.errors and print it. */
static void clusterManagerOnError(sds err) {
    if (cluster_manager.errors == NULL) cluster_manager.errors = listCreate();
    listAddNodeTail(cluster_manager.errors, err);
    clusterManagerLogErr("%s\n", (char *)err);
}

/* Check the slots coverage of the cluster. The 'all_slots' argument must be
 * and array of 16384 bytes. Every covered slot will be set to 1 in the
 * 'all_slots' array. The function returns the total number if covered slots.*/
static int clusterManagerGetCoveredSlots(char *all_slots) {
    if (cluster_manager.nodes == NULL) return 0;
    listIter li;
    listNode *ln;
    listRewind(cluster_manager.nodes, &li);
    int totslots = 0, i;
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *node = ln->value;
        for (i = 0; i < CLUSTER_MANAGER_SLOTS; i++) {
            if (node->slots[i] && !all_slots[i]) {
                all_slots[i] = 1;
                totslots++;
            }
        }
    }
    return totslots;
}

static void clusterManagerPrintSlotsList(list *slots) {
    clusterManagerNode n = {0};
    listIter li;
    listNode *ln;
    listRewind(slots, &li);
    while ((ln = listNext(&li)) != NULL) {
        int slot = atoi(ln->value);
        if (slot >= 0 && slot < CLUSTER_MANAGER_SLOTS) n.slots[slot] = 1;
    }
    sds nodeslist = clusterManagerNodeSlotsString(&n);
    printf("%s\n", nodeslist);
    sdsfree(nodeslist);
}

/* Return the node, among 'nodes' with the greatest number of keys
 * in the specified slot. */
static clusterManagerNode *clusterManagerGetNodeWithMostKeysInSlot(list *nodes, int slot, char **err) {
    clusterManagerNode *node = NULL;
    int numkeys = 0;
    listIter li;
    listNode *ln;
    listRewind(nodes, &li);
    if (err) *err = NULL;
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *n = ln->value;
        if (n->flags & CLUSTER_MANAGER_FLAG_REPLICA || n->replicate) continue;
        redisReply *r = CLUSTER_MANAGER_COMMAND(n, "CLUSTER COUNTKEYSINSLOT %d", slot);
        int success = clusterManagerCheckRedisReply(n, r, err);
        if (success) {
            if (r->integer > numkeys || node == NULL) {
                numkeys = r->integer;
                node = n;
            }
        }
        if (r != NULL) freeReplyObject(r);
        /* If the reply contains errors */
        if (!success) {
            if (err != NULL && *err != NULL) CLUSTER_MANAGER_PRINT_REPLY_ERROR(n, err);
            node = NULL;
            break;
        }
    }
    return node;
}

/* This function returns the primary that has the least number of replicas
 * in the cluster. If there are multiple primaries with the same smaller
 * number of replicas, one at random is returned. */

static clusterManagerNode *clusterManagerNodeWithLeastReplicas(void) {
    clusterManagerNode *node = NULL;
    int lowest_count = 0;
    listIter li;
    listNode *ln;
    listRewind(cluster_manager.nodes, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *n = ln->value;
        if (n->flags & CLUSTER_MANAGER_FLAG_REPLICA) continue;
        if (node == NULL || n->replicas_count < lowest_count) {
            node = n;
            lowest_count = n->replicas_count;
        }
    }
    return node;
}

/* This function returns a random primary node, return NULL if none */

static clusterManagerNode *clusterManagerNodePrimaryRandom(void) {
    int primary_count = 0;
    int idx;
    listIter li;
    listNode *ln;
    listRewind(cluster_manager.nodes, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *n = ln->value;
        if (n->flags & CLUSTER_MANAGER_FLAG_REPLICA) continue;
        primary_count++;
    }

    assert(primary_count > 0);
    srand(time(NULL));
    idx = rand() % primary_count;
    listRewind(cluster_manager.nodes, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *n = ln->value;
        if (n->flags & CLUSTER_MANAGER_FLAG_REPLICA) continue;
        if (!idx--) {
            return n;
        }
    }
    /* Can not be reached */
    assert(0);
    /* Make compiler happy */
    return 0;
}

static int clusterManagerFixSlotsCoverage(char *all_slots) {
    int force_fix = config.cluster_manager_command.flags & CLUSTER_MANAGER_CMD_FLAG_FIX_WITH_UNREACHABLE_PRIMARIES;

    if (cluster_manager.unreachable_primaries > 0 && !force_fix) {
        clusterManagerLogWarn(
            "*** Fixing slots coverage with %d unreachable primaries is dangerous: valkey-cli will assume that slots "
            "about primaries that are not reachable are not covered, and will try to reassign them to the reachable "
            "nodes. This can cause data loss and is rarely what you want to do. If you really want to proceed use the "
            "--cluster-fix-with-unreachable-primaries option.\n",
            cluster_manager.unreachable_primaries);
        exit(1);
    }

    int i, fixed = 0;
    list *none = NULL, *single = NULL, *multi = NULL;
    clusterManagerLogInfo(">>> Fixing slots coverage...\n");
    for (i = 0; i < CLUSTER_MANAGER_SLOTS; i++) {
        int covered = all_slots[i];
        if (!covered) {
            sds slot = sdsfromlonglong((long long)i);
            list *slot_nodes = listCreate();
            sds slot_nodes_str = sdsempty();
            listIter li;
            listNode *ln;
            listRewind(cluster_manager.nodes, &li);
            while ((ln = listNext(&li)) != NULL) {
                clusterManagerNode *n = ln->value;
                if (n->flags & CLUSTER_MANAGER_FLAG_REPLICA || n->replicate) continue;
                redisReply *reply = CLUSTER_MANAGER_COMMAND(n, "CLUSTER GETKEYSINSLOT %d %d", i, 1);
                if (!clusterManagerCheckRedisReply(n, reply, NULL)) {
                    fixed = -1;
                    if (reply) freeReplyObject(reply);
                    goto cleanup;
                }
                assert(reply->type == REDIS_REPLY_ARRAY);
                if (reply->elements > 0) {
                    listAddNodeTail(slot_nodes, n);
                    if (listLength(slot_nodes) > 1) slot_nodes_str = sdscat(slot_nodes_str, ", ");
                    slot_nodes_str = sdscatfmt(slot_nodes_str, "%s:%u", n->ip, n->port);
                }
                freeReplyObject(reply);
            }
            sdsfree(slot_nodes_str);
            dictAdd(clusterManagerUncoveredSlots, slot, slot_nodes);
        }
    }

    /* For every slot, take action depending on the actual condition:
     * 1) No node has keys for this slot.
     * 2) A single node has keys for this slot.
     * 3) Multiple nodes have keys for this slot. */
    none = listCreate();
    single = listCreate();
    multi = listCreate();
    dictIterator *iter = dictGetIterator(clusterManagerUncoveredSlots);
    dictEntry *entry;
    while ((entry = dictNext(iter)) != NULL) {
        sds slot = (sds)dictGetKey(entry);
        list *nodes = (list *)dictGetVal(entry);
        switch (listLength(nodes)) {
        case 0: listAddNodeTail(none, slot); break;
        case 1: listAddNodeTail(single, slot); break;
        default: listAddNodeTail(multi, slot); break;
        }
    }
    dictReleaseIterator(iter);

    /* we want explicit manual confirmation from users for all the fix cases */
    int ignore_force = 1;

    /*  Handle case "1": keys in no node. */
    if (listLength(none) > 0) {
        printf("The following uncovered slots have no keys "
               "across the cluster:\n");
        clusterManagerPrintSlotsList(none);
        if (confirmWithYes("Fix these slots by covering with a random node?", ignore_force)) {
            listIter li;
            listNode *ln;
            listRewind(none, &li);
            while ((ln = listNext(&li)) != NULL) {
                sds slot = ln->value;
                int s = atoi(slot);
                clusterManagerNode *n = clusterManagerNodePrimaryRandom();
                clusterManagerLogInfo(">>> Covering slot %s with %s:%d\n", slot, n->ip, n->port);
                if (!clusterManagerSetSlotOwner(n, s, 0)) {
                    fixed = -1;
                    goto cleanup;
                }
                /* Since CLUSTER ADDSLOTS succeeded, we also update the slot
                 * info into the node struct, in order to keep it synced */
                n->slots[s] = 1;
                fixed++;
            }
        }
    }

    /*  Handle case "2": keys only in one node. */
    if (listLength(single) > 0) {
        printf("The following uncovered slots have keys in just one node:\n");
        clusterManagerPrintSlotsList(single);
        if (confirmWithYes("Fix these slots by covering with those nodes?", ignore_force)) {
            listIter li;
            listNode *ln;
            listRewind(single, &li);
            while ((ln = listNext(&li)) != NULL) {
                sds slot = ln->value;
                int s = atoi(slot);
                dictEntry *entry = dictFind(clusterManagerUncoveredSlots, slot);
                assert(entry != NULL);
                list *nodes = (list *)dictGetVal(entry);
                listNode *fn = listFirst(nodes);
                assert(fn != NULL);
                clusterManagerNode *n = fn->value;
                clusterManagerLogInfo(">>> Covering slot %s with %s:%d\n", slot, n->ip, n->port);
                if (!clusterManagerSetSlotOwner(n, s, 0)) {
                    fixed = -1;
                    goto cleanup;
                }
                /* Since CLUSTER ADDSLOTS succeeded, we also update the slot
                 * info into the node struct, in order to keep it synced */
                n->slots[atoi(slot)] = 1;
                fixed++;
            }
        }
    }

    /* Handle case "3": keys in multiple nodes. */
    if (listLength(multi) > 0) {
        printf("The following uncovered slots have keys in multiple nodes:\n");
        clusterManagerPrintSlotsList(multi);
        if (confirmWithYes("Fix these slots by moving keys "
                           "into a single node?",
                           ignore_force)) {
            listIter li;
            listNode *ln;
            listRewind(multi, &li);
            while ((ln = listNext(&li)) != NULL) {
                sds slot = ln->value;
                dictEntry *entry = dictFind(clusterManagerUncoveredSlots, slot);
                assert(entry != NULL);
                list *nodes = (list *)dictGetVal(entry);
                int s = atoi(slot);
                clusterManagerNode *target = clusterManagerGetNodeWithMostKeysInSlot(nodes, s, NULL);
                if (target == NULL) {
                    fixed = -1;
                    goto cleanup;
                }
                clusterManagerLogInfo(">>> Covering slot %s moving keys "
                                      "to %s:%d\n",
                                      slot, target->ip, target->port);
                if (!clusterManagerSetSlotOwner(target, s, 1)) {
                    fixed = -1;
                    goto cleanup;
                }
                /* Since CLUSTER ADDSLOTS succeeded, we also update the slot
                 * info into the node struct, in order to keep it synced */
                target->slots[atoi(slot)] = 1;
                listIter nli;
                listNode *nln;
                listRewind(nodes, &nli);
                while ((nln = listNext(&nli)) != NULL) {
                    clusterManagerNode *src = nln->value;
                    if (src == target) continue;
                    /* Assign the slot to target node in the source node. */
                    if (!clusterManagerSetSlot(src, target, s, "NODE", NULL)) fixed = -1;
                    if (fixed < 0) goto cleanup;
                    /* Set the source node in 'importing' state
                     * (even if we will actually migrate keys away)
                     * in order to avoid receiving redirections
                     * for MIGRATE. */
                    if (!clusterManagerSetSlot(src, target, s, "IMPORTING", NULL)) fixed = -1;
                    if (fixed < 0) goto cleanup;
                    int opts = CLUSTER_MANAGER_OPT_VERBOSE | CLUSTER_MANAGER_OPT_COLD;
                    if (!clusterManagerMoveSlot(src, target, s, opts, NULL)) {
                        fixed = -1;
                        goto cleanup;
                    }
                    if (!clusterManagerClearSlotStatus(src, s)) fixed = -1;
                    if (fixed < 0) goto cleanup;
                }
                fixed++;
            }
        }
    }
cleanup:
    if (none) listRelease(none);
    if (single) listRelease(single);
    if (multi) listRelease(multi);
    return fixed;
}

/* Slot 'slot' was found to be in importing or migrating state in one or
 * more nodes. This function fixes this condition by migrating keys where
 * it seems more sensible. */
static int clusterManagerFixOpenSlot(int slot) {
    int force_fix = config.cluster_manager_command.flags & CLUSTER_MANAGER_CMD_FLAG_FIX_WITH_UNREACHABLE_PRIMARIES;

    if (cluster_manager.unreachable_primaries > 0 && !force_fix) {
        clusterManagerLogWarn(
            "*** Fixing open slots with %d unreachable primaries is dangerous: valkey-cli will assume that slots about "
            "primaries that are not reachable are not covered, and will try to reassign them to the reachable nodes. "
            "This can cause data loss and is rarely what you want to do. If you really want to proceed use the "
            "--cluster-fix-with-unreachable-primaries option.\n",
            cluster_manager.unreachable_primaries);
        exit(1);
    }

    clusterManagerLogInfo(">>> Fixing open slot %d\n", slot);
    /* Try to obtain the current slot owner, according to the current
     * nodes configuration. */
    int success = 1;
    list *owners = listCreate(); /* List of nodes claiming some ownership.
                                    it could be stating in the configuration
                                    to have the node ownership, or just
                                    holding keys for such slot. */
    list *migrating = listCreate();
    list *importing = listCreate();
    sds migrating_str = sdsempty();
    sds importing_str = sdsempty();
    clusterManagerNode *owner = NULL; /* The obvious slot owner if any. */

    /* Iterate all the nodes, looking for potential owners of this slot. */
    listIter li;
    listNode *ln;
    listRewind(cluster_manager.nodes, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *n = ln->value;
        if (n->flags & CLUSTER_MANAGER_FLAG_REPLICA) continue;
        if (n->slots[slot]) {
            listAddNodeTail(owners, n);
        } else {
            redisReply *r = CLUSTER_MANAGER_COMMAND(n, "CLUSTER COUNTKEYSINSLOT %d", slot);
            success = clusterManagerCheckRedisReply(n, r, NULL);
            if (success && r->integer > 0) {
                clusterManagerLogWarn("*** Found keys about slot %d "
                                      "in non-owner node %s:%d!\n",
                                      slot, n->ip, n->port);
                listAddNodeTail(owners, n);
            }
            if (r) freeReplyObject(r);
            if (!success) goto cleanup;
        }
    }

    /* If we have only a single potential owner for this slot,
     * set it as "owner". */
    if (listLength(owners) == 1) owner = listFirst(owners)->value;

    /* Scan the list of nodes again, in order to populate the
     * list of nodes in importing or migrating state for
     * this slot. */
    listRewind(cluster_manager.nodes, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *n = ln->value;
        if (n->flags & CLUSTER_MANAGER_FLAG_REPLICA) continue;
        int is_migrating = 0, is_importing = 0;
        if (n->migrating) {
            for (int i = 0; i < n->migrating_count; i += 2) {
                sds migrating_slot = n->migrating[i];
                if (atoi(migrating_slot) == slot) {
                    char *sep = (listLength(migrating) == 0 ? "" : ",");
                    migrating_str = sdscatfmt(migrating_str, "%s%s:%u", sep, n->ip, n->port);
                    listAddNodeTail(migrating, n);
                    is_migrating = 1;
                    break;
                }
            }
        }
        if (!is_migrating && n->importing) {
            for (int i = 0; i < n->importing_count; i += 2) {
                sds importing_slot = n->importing[i];
                if (atoi(importing_slot) == slot) {
                    char *sep = (listLength(importing) == 0 ? "" : ",");
                    importing_str = sdscatfmt(importing_str, "%s%s:%u", sep, n->ip, n->port);
                    listAddNodeTail(importing, n);
                    is_importing = 1;
                    break;
                }
            }
        }

        /* If the node is neither migrating nor importing and it's not
         * the owner, then is added to the importing list in case
         * it has keys in the slot. */
        if (!is_migrating && !is_importing && n != owner) {
            redisReply *r = CLUSTER_MANAGER_COMMAND(n, "CLUSTER COUNTKEYSINSLOT %d", slot);
            success = clusterManagerCheckRedisReply(n, r, NULL);
            if (success && r->integer > 0) {
                clusterManagerLogWarn("*** Found keys about slot %d "
                                      "in node %s:%d!\n",
                                      slot, n->ip, n->port);
                char *sep = (listLength(importing) == 0 ? "" : ",");
                importing_str = sdscatfmt(importing_str, "%s%s:%u", sep, n->ip, n->port);
                listAddNodeTail(importing, n);
            }
            if (r) freeReplyObject(r);
            if (!success) goto cleanup;
        }
    }
    if (sdslen(migrating_str) > 0) printf("Set as migrating in: %s\n", migrating_str);
    if (sdslen(importing_str) > 0) printf("Set as importing in: %s\n", importing_str);

    /* If there is no slot owner, set as owner the node with the biggest
     * number of keys, among the set of migrating / importing nodes. */
    if (owner == NULL) {
        clusterManagerLogInfo(">>> No single clear owner for the slot, "
                              "selecting an owner by # of keys...\n");
        owner = clusterManagerGetNodeWithMostKeysInSlot(cluster_manager.nodes, slot, NULL);
        // If we still don't have an owner, we can't fix it.
        if (owner == NULL) {
            clusterManagerLogErr("[ERR] Can't select a slot owner. "
                                 "Impossible to fix.\n");
            success = 0;
            goto cleanup;
        }

        // Use ADDSLOTS to assign the slot.
        clusterManagerLogWarn("*** Configuring %s:%d as the slot owner\n", owner->ip, owner->port);
        success = clusterManagerClearSlotStatus(owner, slot);
        if (!success) goto cleanup;
        success = clusterManagerSetSlotOwner(owner, slot, 0);
        if (!success) goto cleanup;
        /* Since CLUSTER ADDSLOTS succeeded, we also update the slot
         * info into the node struct, in order to keep it synced */
        owner->slots[slot] = 1;
        /* Remove the owner from the list of migrating/importing
         * nodes. */
        clusterManagerRemoveNodeFromList(migrating, owner);
        clusterManagerRemoveNodeFromList(importing, owner);
    }

    /* If there are multiple owners of the slot, we need to fix it
     * so that a single node is the owner and all the other nodes
     * are in importing state. Later the fix can be handled by one
     * of the base cases above.
     *
     * Note that this case also covers multiple nodes having the slot
     * in migrating state, since migrating is a valid state only for
     * slot owners. */
    if (listLength(owners) > 1) {
        /* Owner cannot be NULL at this point, since if there are more owners,
         * the owner has been set in the previous condition (owner == NULL). */
        assert(owner != NULL);
        listRewind(owners, &li);
        while ((ln = listNext(&li)) != NULL) {
            clusterManagerNode *n = ln->value;
            if (n == owner) continue;
            success = clusterManagerDelSlot(n, slot, 1);
            if (!success) goto cleanup;
            n->slots[slot] = 0;
            /* Assign the slot to the owner in the node 'n' configuration.' */
            success = clusterManagerSetSlot(n, owner, slot, "node", NULL);
            if (!success) goto cleanup;
            success = clusterManagerSetSlot(n, owner, slot, "importing", NULL);
            if (!success) goto cleanup;
            /* Avoid duplicates. */
            clusterManagerRemoveNodeFromList(importing, n);
            listAddNodeTail(importing, n);
            /* Ensure that the node is not in the migrating list. */
            clusterManagerRemoveNodeFromList(migrating, n);
        }
    }
    int move_opts = CLUSTER_MANAGER_OPT_VERBOSE;

    /* Case 1: The slot is in migrating state in one node, and in
     *         importing state in 1 node. That's trivial to address. */
    if (listLength(migrating) == 1 && listLength(importing) == 1) {
        clusterManagerNode *src = listFirst(migrating)->value;
        clusterManagerNode *dst = listFirst(importing)->value;
        clusterManagerLogInfo(">>> Case 1: Moving slot %d from "
                              "%s:%d to %s:%d\n",
                              slot, src->ip, src->port, dst->ip, dst->port);
        move_opts |= CLUSTER_MANAGER_OPT_UPDATE;
        success = clusterManagerMoveSlot(src, dst, slot, move_opts, NULL);
    }

    /* Case 2: There are multiple nodes that claim the slot as importing,
     * they probably got keys about the slot after a restart so opened
     * the slot. In this case we just move all the keys to the owner
     * according to the configuration. */
    else if (listLength(migrating) == 0 && listLength(importing) > 0) {
        clusterManagerLogInfo(">>> Case 2: Moving all the %d slot keys to its "
                              "owner %s:%d\n",
                              slot, owner->ip, owner->port);
        move_opts |= CLUSTER_MANAGER_OPT_COLD;
        listRewind(importing, &li);
        while ((ln = listNext(&li)) != NULL) {
            clusterManagerNode *n = ln->value;
            if (n == owner) continue;
            success = clusterManagerMoveSlot(n, owner, slot, move_opts, NULL);
            if (!success) goto cleanup;
            clusterManagerLogInfo(">>> Setting %d as STABLE in "
                                  "%s:%d\n",
                                  slot, n->ip, n->port);
            success = clusterManagerClearSlotStatus(n, slot);
            if (!success) goto cleanup;
        }
        /* Since the slot has been moved in "cold" mode, ensure that all the
         * other nodes update their own configuration about the slot itself. */
        listRewind(cluster_manager.nodes, &li);
        while ((ln = listNext(&li)) != NULL) {
            clusterManagerNode *n = ln->value;
            if (n == owner) continue;
            if (n->flags & CLUSTER_MANAGER_FLAG_REPLICA) continue;
            success = clusterManagerSetSlot(n, owner, slot, "NODE", NULL);
            if (!success) goto cleanup;
        }
    }

    /* Case 3: The slot is in migrating state in one node but multiple
     * other nodes claim to be in importing state and don't have any key in
     * the slot. We search for the importing node having the same ID as
     * the destination node of the migrating node.
     * In that case we move the slot from the migrating node to this node and
     * we close the importing states on all the other importing nodes.
     * If no importing node has the same ID as the destination node of the
     * migrating node, the slot's state is closed on both the migrating node
     * and the importing nodes. */
    else if (listLength(migrating) == 1 && listLength(importing) > 1) {
        int try_to_fix = 1;
        clusterManagerNode *src = listFirst(migrating)->value;
        clusterManagerNode *dst = NULL;
        sds target_id = NULL;
        for (int i = 0; i < src->migrating_count; i += 2) {
            sds migrating_slot = src->migrating[i];
            if (atoi(migrating_slot) == slot) {
                target_id = src->migrating[i + 1];
                break;
            }
        }
        assert(target_id != NULL);
        listIter li;
        listNode *ln;
        listRewind(importing, &li);
        while ((ln = listNext(&li)) != NULL) {
            clusterManagerNode *n = ln->value;
            int count = clusterManagerCountKeysInSlot(n, slot);
            if (count > 0) {
                try_to_fix = 0;
                break;
            }
            if (strcmp(n->name, target_id) == 0) dst = n;
        }
        if (!try_to_fix) goto unhandled_case;
        if (dst != NULL) {
            clusterManagerLogInfo(">>> Case 3: Moving slot %d from %s:%d to "
                                  "%s:%d and closing it on all the other "
                                  "importing nodes.\n",
                                  slot, src->ip, src->port, dst->ip, dst->port);
            /* Move the slot to the destination node. */
            success = clusterManagerMoveSlot(src, dst, slot, move_opts, NULL);
            if (!success) goto cleanup;
            /* Close slot on all the other importing nodes. */
            listRewind(importing, &li);
            while ((ln = listNext(&li)) != NULL) {
                clusterManagerNode *n = ln->value;
                if (dst == n) continue;
                success = clusterManagerClearSlotStatus(n, slot);
                if (!success) goto cleanup;
            }
        } else {
            clusterManagerLogInfo(">>> Case 3: Closing slot %d on both "
                                  "migrating and importing nodes.\n",
                                  slot);
            /* Close the slot on both the migrating node and the importing
             * nodes. */
            success = clusterManagerClearSlotStatus(src, slot);
            if (!success) goto cleanup;
            listRewind(importing, &li);
            while ((ln = listNext(&li)) != NULL) {
                clusterManagerNode *n = ln->value;
                success = clusterManagerClearSlotStatus(n, slot);
                if (!success) goto cleanup;
            }
        }
    } else {
        int try_to_close_slot = (listLength(importing) == 0 && listLength(migrating) == 1);
        if (try_to_close_slot) {
            clusterManagerNode *n = listFirst(migrating)->value;
            if (!owner || owner != n) {
                redisReply *r = CLUSTER_MANAGER_COMMAND(n, "CLUSTER GETKEYSINSLOT %d %d", slot, 10);
                success = clusterManagerCheckRedisReply(n, r, NULL);
                if (r) {
                    if (success) try_to_close_slot = (r->elements == 0);
                    freeReplyObject(r);
                }
                if (!success) goto cleanup;
            }
        }
        /* Case 4: There are no slots claiming to be in importing state, but
         * there is a migrating node that actually don't have any key or is the
         * slot owner. We can just close the slot, probably a reshard
         * interrupted in the middle. */
        if (try_to_close_slot) {
            clusterManagerNode *n = listFirst(migrating)->value;
            clusterManagerLogInfo(">>> Case 4: Closing slot %d on %s:%d\n", slot, n->ip, n->port);
            redisReply *r = CLUSTER_MANAGER_COMMAND(n, "CLUSTER SETSLOT %d %s", slot, "STABLE");
            success = clusterManagerCheckRedisReply(n, r, NULL);
            if (r) freeReplyObject(r);
            if (!success) goto cleanup;
        } else {
        unhandled_case:
            success = 0;
            clusterManagerLogErr("[ERR] Sorry, valkey-cli can't fix this slot "
                                 "yet (work in progress). Slot is set as "
                                 "migrating in %s, as importing in %s, "
                                 "owner is %s:%d\n",
                                 migrating_str, importing_str, owner->ip, owner->port);
        }
    }
cleanup:
    listRelease(owners);
    listRelease(migrating);
    listRelease(importing);
    sdsfree(migrating_str);
    sdsfree(importing_str);
    return success;
}

static int clusterManagerFixMultipleSlotOwners(int slot, list *owners) {
    clusterManagerLogInfo(">>> Fixing multiple owners for slot %d...\n", slot);
    int success = 0;
    assert(listLength(owners) > 1);
    clusterManagerNode *owner = clusterManagerGetNodeWithMostKeysInSlot(owners, slot, NULL);
    if (!owner) owner = listFirst(owners)->value;
    clusterManagerLogInfo(">>> Setting slot %d owner: %s:%d\n", slot, owner->ip, owner->port);
    /* Set the slot owner. */
    if (!clusterManagerSetSlotOwner(owner, slot, 0)) return 0;
    listIter li;
    listNode *ln;
    listRewind(cluster_manager.nodes, &li);
    /* Update configuration in all the other primary nodes by assigning the slot
     * itself to the new owner, and by eventually migrating keys if the node
     * has keys for the slot. */
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *n = ln->value;
        if (n == owner) continue;
        if (n->flags & CLUSTER_MANAGER_FLAG_REPLICA) continue;
        int count = clusterManagerCountKeysInSlot(n, slot);
        success = (count >= 0);
        if (!success) break;
        clusterManagerDelSlot(n, slot, 1);
        if (!clusterManagerSetSlot(n, owner, slot, "node", NULL)) return 0;
        if (count > 0) {
            int opts = CLUSTER_MANAGER_OPT_VERBOSE | CLUSTER_MANAGER_OPT_COLD;
            success = clusterManagerMoveSlot(n, owner, slot, opts, NULL);
            if (!success) break;
        }
    }
    return success;
}

static int clusterManagerCheckCluster(int quiet) {
    listNode *ln = listFirst(cluster_manager.nodes);
    if (!ln) return 0;
    clusterManagerNode *node = ln->value;
    clusterManagerLogInfo(">>> Performing Cluster Check (using node %s:%d)\n", node->ip, node->port);
    int result = 1, consistent = 0;
    int do_fix = config.cluster_manager_command.flags & CLUSTER_MANAGER_CMD_FLAG_FIX;
    if (!quiet) clusterManagerShowNodes();
    consistent = clusterManagerIsConfigConsistent();
    if (!consistent) {
        sds err = sdsnew("[ERR] Nodes don't agree about configuration!");
        clusterManagerOnError(err);
        result = 0;
    } else {
        clusterManagerLogOk("[OK] All nodes agree about slots "
                            "configuration.\n");
    }
    /* Check open slots */
    clusterManagerLogInfo(">>> Check for open slots...\n");
    listIter li;
    listRewind(cluster_manager.nodes, &li);
    int i;
    dict *open_slots = NULL;
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *n = ln->value;
        if (n->migrating != NULL) {
            if (open_slots == NULL) open_slots = dictCreate(&clusterManagerDictType);
            sds errstr = sdsempty();
            errstr = sdscatprintf(errstr,
                                  "[WARNING] Node %s:%d has slots in "
                                  "migrating state ",
                                  n->ip, n->port);
            for (i = 0; i < n->migrating_count; i += 2) {
                sds slot = n->migrating[i];
                dictReplace(open_slots, slot, sdsdup(n->migrating[i + 1]));
                char *fmt = (i > 0 ? ",%S" : "%S");
                errstr = sdscatfmt(errstr, fmt, slot);
            }
            errstr = sdscat(errstr, ".");
            clusterManagerOnError(errstr);
        }
        if (n->importing != NULL) {
            if (open_slots == NULL) open_slots = dictCreate(&clusterManagerDictType);
            sds errstr = sdsempty();
            errstr = sdscatprintf(errstr,
                                  "[WARNING] Node %s:%d has slots in "
                                  "importing state ",
                                  n->ip, n->port);
            for (i = 0; i < n->importing_count; i += 2) {
                sds slot = n->importing[i];
                dictReplace(open_slots, slot, sdsdup(n->importing[i + 1]));
                char *fmt = (i > 0 ? ",%S" : "%S");
                errstr = sdscatfmt(errstr, fmt, slot);
            }
            errstr = sdscat(errstr, ".");
            clusterManagerOnError(errstr);
        }
    }
    if (open_slots != NULL) {
        result = 0;
        dictIterator *iter = dictGetIterator(open_slots);
        dictEntry *entry;
        sds errstr = sdsnew("[WARNING] The following slots are open: ");
        i = 0;
        while ((entry = dictNext(iter)) != NULL) {
            sds slot = (sds)dictGetKey(entry);
            char *fmt = (i++ > 0 ? ",%S" : "%S");
            errstr = sdscatfmt(errstr, fmt, slot);
        }
        clusterManagerLogErr("%s.\n", (char *)errstr);
        sdsfree(errstr);
        if (do_fix) {
            /* Fix open slots. */
            dictReleaseIterator(iter);
            iter = dictGetIterator(open_slots);
            while ((entry = dictNext(iter)) != NULL) {
                sds slot = (sds)dictGetKey(entry);
                result = clusterManagerFixOpenSlot(atoi(slot));
                if (!result) break;
            }
        }
        dictReleaseIterator(iter);
        dictRelease(open_slots);
    }
    clusterManagerLogInfo(">>> Check slots coverage...\n");
    char slots[CLUSTER_MANAGER_SLOTS];
    memset(slots, 0, CLUSTER_MANAGER_SLOTS);
    int coverage = clusterManagerGetCoveredSlots(slots);
    if (coverage == CLUSTER_MANAGER_SLOTS) {
        clusterManagerLogOk("[OK] All %d slots covered.\n", CLUSTER_MANAGER_SLOTS);
    } else {
        sds err = sdsempty();
        err = sdscatprintf(err,
                           "[ERR] Not all %d slots are "
                           "covered by nodes.\n",
                           CLUSTER_MANAGER_SLOTS);
        clusterManagerOnError(err);
        result = 0;
        if (do_fix /* && result*/) {
            dictType dtype = clusterManagerDictType;
            dtype.keyDestructor = dictSdsDestructor;
            dtype.valDestructor = dictListDestructor;
            clusterManagerUncoveredSlots = dictCreate(&dtype);
            int fixed = clusterManagerFixSlotsCoverage(slots);
            if (fixed > 0) result = 1;
        }
    }
    int search_multiple_owners = config.cluster_manager_command.flags & CLUSTER_MANAGER_CMD_FLAG_CHECK_OWNERS;
    if (search_multiple_owners) {
        /* Check whether there are multiple owners, even when slots are
         * fully covered and there are no open slots. */
        clusterManagerLogInfo(">>> Check for multiple slot owners...\n");
        int slot = 0, slots_with_multiple_owners = 0;
        for (; slot < CLUSTER_MANAGER_SLOTS; slot++) {
            listIter li;
            listNode *ln;
            listRewind(cluster_manager.nodes, &li);
            list *owners = listCreate();
            while ((ln = listNext(&li)) != NULL) {
                clusterManagerNode *n = ln->value;
                if (n->flags & CLUSTER_MANAGER_FLAG_REPLICA) continue;
                if (n->slots[slot])
                    listAddNodeTail(owners, n);
                else {
                    /* Nodes having keys for the slot will be considered
                     * owners too. */
                    int count = clusterManagerCountKeysInSlot(n, slot);
                    if (count > 0) listAddNodeTail(owners, n);
                }
            }
            if (listLength(owners) > 1) {
                result = 0;
                clusterManagerLogErr("[WARNING] Slot %d has %d owners:\n", slot, listLength(owners));
                listRewind(owners, &li);
                while ((ln = listNext(&li)) != NULL) {
                    clusterManagerNode *n = ln->value;
                    clusterManagerLogErr("    %s:%d\n", n->ip, n->port);
                }
                slots_with_multiple_owners++;
                if (do_fix) {
                    result = clusterManagerFixMultipleSlotOwners(slot, owners);
                    if (!result) {
                        clusterManagerLogErr("Failed to fix multiple owners "
                                             "for slot %d\n",
                                             slot);
                        listRelease(owners);
                        break;
                    } else
                        slots_with_multiple_owners--;
                }
            }
            listRelease(owners);
        }
        if (slots_with_multiple_owners == 0) clusterManagerLogOk("[OK] No multiple owners found.\n");
    }
    return result;
}

static clusterManagerNode *clusterNodeForResharding(char *id, clusterManagerNode *target, int *raise_err) {
    clusterManagerNode *node = NULL;
    const char *invalid_node_msg = "*** The specified node (%s) is not known "
                                   "or not a primary, please retry.\n";
    node = clusterManagerNodeByName(id);
    *raise_err = 0;
    if (!node || node->flags & CLUSTER_MANAGER_FLAG_REPLICA) {
        clusterManagerLogErr(invalid_node_msg, id);
        *raise_err = 1;
        return NULL;
    } else if (target != NULL) {
        if (!strcmp(node->name, target->name)) {
            clusterManagerLogErr("*** It is not possible to use "
                                 "the target node as "
                                 "source node.\n");
            return NULL;
        }
    }
    return node;
}

static list *clusterManagerComputeReshardTable(list *sources, int numslots) {
    list *moved = listCreate();
    int src_count = listLength(sources), i = 0, tot_slots = 0, j;
    clusterManagerNode **sorted = zmalloc(src_count * sizeof(*sorted));
    listIter li;
    listNode *ln;
    listRewind(sources, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *node = ln->value;
        tot_slots += node->slots_count;
        sorted[i++] = node;
    }
    qsort(sorted, src_count, sizeof(clusterManagerNode *), clusterManagerSlotCountCompareDesc);
    for (i = 0; i < src_count; i++) {
        clusterManagerNode *node = sorted[i];
        float n = ((float)numslots / tot_slots * node->slots_count);
        if (i == 0)
            n = ceil(n);
        else
            n = floor(n);
        int max = (int)n, count = 0;
        for (j = 0; j < CLUSTER_MANAGER_SLOTS; j++) {
            int slot = node->slots[j];
            if (!slot) continue;
            if (count >= max || (int)listLength(moved) >= numslots) break;
            clusterManagerReshardTableItem *item = zmalloc(sizeof(*item));
            item->source = node;
            item->slot = j;
            listAddNodeTail(moved, item);
            count++;
        }
    }
    zfree(sorted);
    return moved;
}

static void clusterManagerShowReshardTable(list *table) {
    listIter li;
    listNode *ln;
    listRewind(table, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerReshardTableItem *item = ln->value;
        clusterManagerNode *n = item->source;
        printf("    Moving slot %d from %s\n", item->slot, (char *)n->name);
    }
}

static void clusterManagerReleaseReshardTable(list *table) {
    if (table != NULL) {
        listIter li;
        listNode *ln;
        listRewind(table, &li);
        while ((ln = listNext(&li)) != NULL) {
            clusterManagerReshardTableItem *item = ln->value;
            zfree(item);
        }
        listRelease(table);
    }
}

static void clusterManagerLog(int level, const char *fmt, ...) {
    int use_colors = (config.cluster_manager_command.flags & CLUSTER_MANAGER_CMD_FLAG_COLOR);
    if (use_colors) {
        printf("\033[");
        switch (level) {
        case CLUSTER_MANAGER_LOG_LVL_INFO: printf(LOG_COLOR_BOLD); break;
        case CLUSTER_MANAGER_LOG_LVL_WARN: printf(LOG_COLOR_YELLOW); break;
        case CLUSTER_MANAGER_LOG_LVL_ERR: printf(LOG_COLOR_RED); break;
        case CLUSTER_MANAGER_LOG_LVL_SUCCESS: printf(LOG_COLOR_GREEN); break;
        default: printf(LOG_COLOR_RESET); break;
        }
    }
    va_list ap;
    va_start(ap, fmt);
    vprintf(fmt, ap);
    va_end(ap);
    if (use_colors) printf("\033[" LOG_COLOR_RESET);
}

static void clusterManagerNodeArrayInit(clusterManagerNodeArray *array, int alloc_len) {
    array->nodes = zcalloc(alloc_len * sizeof(clusterManagerNode *));
    array->alloc = array->nodes;
    array->len = alloc_len;
    array->count = 0;
}

/* Reset array->nodes to the original array allocation and re-count non-NULL
 * nodes. */
static void clusterManagerNodeArrayReset(clusterManagerNodeArray *array) {
    if (array->nodes > array->alloc) {
        array->len = array->nodes - array->alloc;
        array->nodes = array->alloc;
        array->count = 0;
        int i = 0;
        for (; i < array->len; i++) {
            if (array->nodes[i] != NULL) array->count++;
        }
    }
}

/* Shift array->nodes and store the shifted node into 'nodeptr'. */
static void clusterManagerNodeArrayShift(clusterManagerNodeArray *array, clusterManagerNode **nodeptr) {
    assert(array->len > 0);
    /* If the first node to be shifted is not NULL, decrement count. */
    if (*array->nodes != NULL) array->count--;
    /* Store the first node to be shifted into 'nodeptr'. */
    *nodeptr = *array->nodes;
    /* Shift the nodes array and decrement length. */
    array->nodes++;
    array->len--;
}

static void clusterManagerNodeArrayAdd(clusterManagerNodeArray *array, clusterManagerNode *node) {
    assert(array->len > 0);
    assert(node != NULL);
    assert(array->count < array->len);
    array->nodes[array->count++] = node;
}

static void clusterManagerPrintNotEmptyNodeError(clusterManagerNode *node, char *err) {
    char *msg;
    if (err)
        msg = err;
    else {
        msg = "is not empty. Either the node already knows other "
              "nodes (check with CLUSTER NODES) or contains some "
              "key in database 0.";
    }
    clusterManagerLogErr("[ERR] Node %s:%d %s\n", node->ip, node->port, msg);
}

static void clusterManagerPrintNotClusterNodeError(clusterManagerNode *node, char *err) {
    char *msg = (err ? err : "is not configured as a cluster node.");
    clusterManagerLogErr("[ERR] Node %s:%d %s\n", node->ip, node->port, msg);
}

/* Execute valkey-cli in Cluster Manager mode */
static void clusterManagerMode(clusterManagerCommandProc *proc) {
    int argc = config.cluster_manager_command.argc;
    char **argv = config.cluster_manager_command.argv;
    cluster_manager.nodes = NULL;
    int success = proc(argc, argv);

    /* Initialized in createClusterManagerCommand. */
    if (config.stdin_lastarg) {
        zfree(config.cluster_manager_command.argv);
        sdsfree(config.cluster_manager_command.stdin_arg);
    } else if (config.stdin_tag_arg) {
        sdsfree(config.cluster_manager_command.stdin_arg);
    }
    freeClusterManager();

    exit(success ? 0 : 1);
}

/* Cluster Manager Commands */

static int clusterManagerCommandCreate(int argc, char **argv) {
    int i, j, success = 1;
    cluster_manager.nodes = listCreate();
    for (i = 0; i < argc; i++) {
        char *addr = argv[i];
        char *ip = NULL;
        int port = 0;
        if (!parseClusterNodeAddress(addr, &ip, &port, NULL)) {
            fprintf(stderr, "Invalid address format: %s\n", addr);
            return 0;
        }

        clusterManagerNode *node = clusterManagerNewNode(ip, port, 0);
        if (!clusterManagerNodeConnect(node)) {
            freeClusterManagerNode(node);
            return 0;
        }
        char *err = NULL;
        if (!clusterManagerNodeIsCluster(node, &err)) {
            clusterManagerPrintNotClusterNodeError(node, err);
            if (err) zfree(err);
            freeClusterManagerNode(node);
            return 0;
        }
        err = NULL;
        if (!clusterManagerNodeLoadInfo(node, 0, &err)) {
            if (err) {
                CLUSTER_MANAGER_PRINT_REPLY_ERROR(node, err);
                zfree(err);
            }
            freeClusterManagerNode(node);
            return 0;
        }
        err = NULL;
        if (!clusterManagerNodeIsEmpty(node, &err)) {
            clusterManagerPrintNotEmptyNodeError(node, err);
            if (err) zfree(err);
            freeClusterManagerNode(node);
            return 0;
        }
        listAddNodeTail(cluster_manager.nodes, node);
    }
    int node_len = cluster_manager.nodes->len;
    int replicas = config.cluster_manager_command.replicas;
    int primaries_count = CLUSTER_MANAGER_PRIMARIES_COUNT(node_len, replicas);
    if (primaries_count < 3) {
        clusterManagerLogErr("*** ERROR: Invalid configuration for cluster creation.\n"
                             "*** Valkey Cluster requires at least 3 primary nodes.\n"
                             "*** This is not possible with %d nodes and %d replicas per node.",
                             node_len, replicas);
        clusterManagerLogErr("\n*** At least %d nodes are required.\n", 3 * (replicas + 1));
        return 0;
    }
    clusterManagerLogInfo(">>> Performing hash slots allocation "
                          "on %d nodes...\n",
                          node_len);
    int interleaved_len = 0, ip_count = 0;
    clusterManagerNode **interleaved = zcalloc(node_len * sizeof(**interleaved));
    char **ips = zcalloc(node_len * sizeof(char *));
    clusterManagerNodeArray *ip_nodes = zcalloc(node_len * sizeof(*ip_nodes));
    listIter li;
    listNode *ln;
    listRewind(cluster_manager.nodes, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *n = ln->value;
        int found = 0;
        for (i = 0; i < ip_count; i++) {
            char *ip = ips[i];
            if (!strcmp(ip, n->ip)) {
                found = 1;
                break;
            }
        }
        if (!found) {
            ips[ip_count++] = n->ip;
        }
        clusterManagerNodeArray *node_array = &(ip_nodes[i]);
        if (node_array->nodes == NULL) clusterManagerNodeArrayInit(node_array, node_len);
        clusterManagerNodeArrayAdd(node_array, n);
    }
    while (interleaved_len < node_len) {
        for (i = 0; i < ip_count; i++) {
            clusterManagerNodeArray *node_array = &(ip_nodes[i]);
            if (node_array->count > 0) {
                clusterManagerNode *n = NULL;
                clusterManagerNodeArrayShift(node_array, &n);
                interleaved[interleaved_len++] = n;
            }
        }
    }
    clusterManagerNode **primaries = interleaved;
    interleaved += primaries_count;
    interleaved_len -= primaries_count;
    float slots_per_node = CLUSTER_MANAGER_SLOTS / (float)primaries_count;
    long first = 0;
    float cursor = 0.0f;
    for (i = 0; i < primaries_count; i++) {
        clusterManagerNode *primary = primaries[i];
        long last = lround(cursor + slots_per_node - 1);
        if (last > CLUSTER_MANAGER_SLOTS || i == (primaries_count - 1)) last = CLUSTER_MANAGER_SLOTS - 1;
        if (last < first) last = first;
        printf("Primary[%d] -> Slots %ld - %ld\n", i, first, last);
        primary->slots_count = 0;
        for (j = first; j <= last; j++) {
            primary->slots[j] = 1;
            primary->slots_count++;
        }
        primary->dirty = 1;
        first = last + 1;
        cursor += slots_per_node;
    }

    /* Rotating the list sometimes helps to get better initial
     * anti-affinity before the optimizer runs. */
    clusterManagerNode *first_node = interleaved[0];
    for (i = 0; i < (interleaved_len - 1); i++) interleaved[i] = interleaved[i + 1];
    interleaved[interleaved_len - 1] = first_node;
    int assign_unused = 0, available_count = interleaved_len;
assign_replicas:
    for (i = 0; i < primaries_count; i++) {
        clusterManagerNode *primary = primaries[i];
        int assigned_replicas = 0;
        while (assigned_replicas < replicas) {
            if (available_count == 0) break;
            clusterManagerNode *found = NULL, *replica = NULL;
            int firstNodeIdx = -1;
            for (j = 0; j < interleaved_len; j++) {
                clusterManagerNode *n = interleaved[j];
                if (n == NULL) continue;
                if (strcmp(n->ip, primary->ip)) {
                    found = n;
                    interleaved[j] = NULL;
                    break;
                }
                if (firstNodeIdx < 0) firstNodeIdx = j;
            }
            if (found)
                replica = found;
            else if (firstNodeIdx >= 0) {
                replica = interleaved[firstNodeIdx];
                interleaved_len -= (firstNodeIdx + 1);
                interleaved += (firstNodeIdx + 1);
            }
            if (replica != NULL) {
                assigned_replicas++;
                available_count--;
                if (replica->replicate) sdsfree(replica->replicate);
                replica->replicate = sdsnew(primary->name);
                replica->dirty = 1;
            } else
                break;
            printf("Adding replica %s:%d to %s:%d\n", replica->ip, replica->port, primary->ip, primary->port);
            if (assign_unused) break;
        }
    }
    if (!assign_unused && available_count > 0) {
        assign_unused = 1;
        printf("Adding extra replicas...\n");
        goto assign_replicas;
    }
    for (i = 0; i < ip_count; i++) {
        clusterManagerNodeArray *node_array = ip_nodes + i;
        clusterManagerNodeArrayReset(node_array);
    }
    clusterManagerOptimizeAntiAffinity(ip_nodes, ip_count);
    clusterManagerShowNodes();
    int ignore_force = 0;
    if (confirmWithYes("Can I set the above configuration?", ignore_force)) {
        listRewind(cluster_manager.nodes, &li);
        while ((ln = listNext(&li)) != NULL) {
            clusterManagerNode *node = ln->value;
            char *err = NULL;
            int flushed = clusterManagerFlushNodeConfig(node, &err);
            if (!flushed && node->dirty && !node->replicate) {
                if (err != NULL) {
                    CLUSTER_MANAGER_PRINT_REPLY_ERROR(node, err);
                    zfree(err);
                }
                success = 0;
                goto cleanup;
            } else if (err != NULL)
                zfree(err);
        }
        clusterManagerLogInfo(">>> Nodes configuration updated\n");
        clusterManagerLogInfo(">>> Assign a different config epoch to "
                              "each node\n");
        int config_epoch = 1;
        listRewind(cluster_manager.nodes, &li);
        while ((ln = listNext(&li)) != NULL) {
            clusterManagerNode *node = ln->value;
            redisReply *reply = NULL;
            reply = CLUSTER_MANAGER_COMMAND(node, "cluster set-config-epoch %d", config_epoch++);
            if (reply != NULL) freeReplyObject(reply);
        }
        clusterManagerLogInfo(">>> Sending CLUSTER MEET messages to join "
                              "the cluster\n");
        clusterManagerNode *first = NULL;
        char first_ip[NET_IP_STR_LEN]; /* first->ip may be a hostname */
        listRewind(cluster_manager.nodes, &li);
        while ((ln = listNext(&li)) != NULL) {
            clusterManagerNode *node = ln->value;
            if (first == NULL) {
                first = node;
                /* Although hiredis supports connecting to a hostname, CLUSTER
                 * MEET requires an IP address, so we do a DNS lookup here. */
                int anet_flags = ANET_NONE;
                if (config.prefer_ipv4) anet_flags |= ANET_PREFER_IPV4;
                if (config.prefer_ipv6) anet_flags |= ANET_PREFER_IPV6;
                if (anetResolve(NULL, first->ip, first_ip, sizeof(first_ip), anet_flags) == ANET_ERR) {
                    fprintf(stderr, "Invalid IP address or hostname specified: %s\n", first->ip);
                    success = 0;
                    goto cleanup;
                }
                continue;
            }
            redisReply *reply = NULL;
            if (first->bus_port == 0 || (first->bus_port == first->port + CLUSTER_MANAGER_PORT_INCR)) {
                /* CLUSTER MEET bus-port parameter was added in 4.0.
                 * So if (bus_port == 0) or (bus_port == port + CLUSTER_MANAGER_PORT_INCR),
                 * we just call CLUSTER MEET with 2 arguments, using the old form. */
                reply = CLUSTER_MANAGER_COMMAND(node, "cluster meet %s %d", first_ip, first->port);
            } else {
                reply = CLUSTER_MANAGER_COMMAND(node, "cluster meet %s %d %d", first_ip, first->port, first->bus_port);
            }
            int is_err = 0;
            if (reply != NULL) {
                if ((is_err = reply->type == REDIS_REPLY_ERROR)) CLUSTER_MANAGER_PRINT_REPLY_ERROR(node, reply->str);
                freeReplyObject(reply);
            } else {
                is_err = 1;
                fprintf(stderr, "Failed to send CLUSTER MEET command.\n");
            }
            if (is_err) {
                success = 0;
                goto cleanup;
            }
        }
        /* Give one second for the join to start, in order to avoid that
         * waiting for cluster join will find all the nodes agree about
         * the config as they are still empty with unassigned slots. */
        sleep(1);
        clusterManagerWaitForClusterJoin();
        /* Useful for the replicas */
        listRewind(cluster_manager.nodes, &li);
        while ((ln = listNext(&li)) != NULL) {
            clusterManagerNode *node = ln->value;
            if (!node->dirty) continue;
            char *err = NULL;
            int flushed = clusterManagerFlushNodeConfig(node, &err);
            if (!flushed && !node->replicate) {
                if (err != NULL) {
                    CLUSTER_MANAGER_PRINT_REPLY_ERROR(node, err);
                    zfree(err);
                }
                success = 0;
                goto cleanup;
            } else if (err != NULL) {
                zfree(err);
            }
        }
        // Reset Nodes
        listRewind(cluster_manager.nodes, &li);
        clusterManagerNode *first_node = NULL;
        while ((ln = listNext(&li)) != NULL) {
            clusterManagerNode *node = ln->value;
            if (!first_node)
                first_node = node;
            else
                freeClusterManagerNode(node);
        }
        listEmpty(cluster_manager.nodes);
        if (!clusterManagerLoadInfoFromNode(first_node)) {
            success = 0;
            goto cleanup;
        }
        clusterManagerCheckCluster(0);
    }
cleanup:
    /* Free everything */
    zfree(primaries);
    zfree(ips);
    for (i = 0; i < node_len; i++) {
        clusterManagerNodeArray *node_array = ip_nodes + i;
        CLUSTER_MANAGER_NODE_ARRAY_FREE(node_array);
    }
    zfree(ip_nodes);
    return success;
}

static int clusterManagerCommandAddNode(int argc, char **argv) {
    int success = 1;
    redisReply *reply = NULL;
    redisReply *function_restore_reply = NULL;
    redisReply *function_list_reply = NULL;
    char *ref_ip = NULL, *ip = NULL;
    int ref_port = 0, port = 0;
    if (!getClusterHostFromCmdArgs(argc - 1, argv + 1, &ref_ip, &ref_port)) goto invalid_args;
    if (!getClusterHostFromCmdArgs(1, argv, &ip, &port)) goto invalid_args;
    clusterManagerLogInfo(">>> Adding node %s:%d to cluster %s:%d\n", ip, port, ref_ip, ref_port);
    // Check the existing cluster
    clusterManagerNode *refnode = clusterManagerNewNode(ref_ip, ref_port, 0);
    if (!clusterManagerLoadInfoFromNode(refnode)) return 0;
    if (!clusterManagerCheckCluster(0)) return 0;

    /* If --cluster-primary-id was specified, try to resolve it now so that we
     * abort before starting with the node configuration. */
    clusterManagerNode *primary_node = NULL;
    if (config.cluster_manager_command.flags & CLUSTER_MANAGER_CMD_FLAG_REPLICA) {
        char *primary_id = config.cluster_manager_command.primary_id;
        if (primary_id != NULL) {
            primary_node = clusterManagerNodeByName(primary_id);
            if (primary_node == NULL) {
                clusterManagerLogErr("[ERR] No such primary ID %s\n", primary_id);
                return 0;
            }
        } else {
            primary_node = clusterManagerNodeWithLeastReplicas();
            assert(primary_node != NULL);
            printf("Automatically selected primary %s:%d\n", primary_node->ip, primary_node->port);
        }
    }

    // Add the new node
    clusterManagerNode *new_node = clusterManagerNewNode(ip, port, 0);
    int added = 0;
    if (!clusterManagerNodeConnect(new_node)) {
        clusterManagerLogErr("[ERR] Sorry, can't connect to node %s:%d\n", ip, port);
        success = 0;
        goto cleanup;
    }
    char *err = NULL;
    if (!(success = clusterManagerNodeIsCluster(new_node, &err))) {
        clusterManagerPrintNotClusterNodeError(new_node, err);
        if (err) zfree(err);
        goto cleanup;
    }
    if (!clusterManagerNodeLoadInfo(new_node, 0, &err)) {
        if (err) {
            CLUSTER_MANAGER_PRINT_REPLY_ERROR(new_node, err);
            zfree(err);
        }
        success = 0;
        goto cleanup;
    }
    if (!(success = clusterManagerNodeIsEmpty(new_node, &err))) {
        clusterManagerPrintNotEmptyNodeError(new_node, err);
        if (err) zfree(err);
        goto cleanup;
    }
    clusterManagerNode *first = listFirst(cluster_manager.nodes)->value;
    listAddNodeTail(cluster_manager.nodes, new_node);
    added = 1;

    if (!primary_node) {
        /* Send functions to the new node, if new node is a replica it will get the functions from its primary. */
        clusterManagerLogInfo(">>> Getting functions from cluster\n");
        reply = CLUSTER_MANAGER_COMMAND(refnode, "FUNCTION DUMP");
        if (!clusterManagerCheckRedisReply(refnode, reply, &err)) {
            clusterManagerLogInfo(">>> Failed retrieving Functions from the cluster, "
                                  "skip this step as Valkey version do not support function command (error = '%s')\n",
                                  err ? err : "NULL reply");
            if (err) zfree(err);
        } else {
            assert(reply->type == REDIS_REPLY_STRING);
            clusterManagerLogInfo(">>> Send FUNCTION LIST to %s:%d to verify there is no functions in it\n", ip, port);
            function_list_reply = CLUSTER_MANAGER_COMMAND(new_node, "FUNCTION LIST");
            if (!clusterManagerCheckRedisReply(new_node, function_list_reply, &err)) {
                clusterManagerLogErr(">>> Failed on CLUSTER LIST (error = '%s')\r\n", err ? err : "NULL reply");
                if (err) zfree(err);
                success = 0;
                goto cleanup;
            }
            assert(function_list_reply->type == REDIS_REPLY_ARRAY);
            if (function_list_reply->elements > 0) {
                clusterManagerLogErr(">>> New node already contains functions and can not be added to the cluster. Use "
                                     "FUNCTION FLUSH and try again.\r\n");
                success = 0;
                goto cleanup;
            }
            clusterManagerLogInfo(">>> Send FUNCTION RESTORE to %s:%d\n", ip, port);
            function_restore_reply = CLUSTER_MANAGER_COMMAND(new_node, "FUNCTION RESTORE %b", reply->str, reply->len);
            if (!clusterManagerCheckRedisReply(new_node, function_restore_reply, &err)) {
                clusterManagerLogErr(">>> Failed loading functions to the new node (error = '%s')\r\n",
                                     err ? err : "NULL reply");
                if (err) zfree(err);
                success = 0;
                goto cleanup;
            }
        }
    }

    if (reply) freeReplyObject(reply);

    // Send CLUSTER MEET command to the new node
    clusterManagerLogInfo(">>> Send CLUSTER MEET to node %s:%d to make it "
                          "join the cluster.\n",
                          ip, port);
    /* CLUSTER MEET requires an IP address, so we do a DNS lookup here. */
    char first_ip[NET_IP_STR_LEN];
    int anet_flags = ANET_NONE;
    if (config.prefer_ipv4) anet_flags |= ANET_PREFER_IPV4;
    if (config.prefer_ipv6) anet_flags |= ANET_PREFER_IPV6;
    if (anetResolve(NULL, first->ip, first_ip, sizeof(first_ip), anet_flags) == ANET_ERR) {
        fprintf(stderr, "Invalid IP address or hostname specified: %s\n", first->ip);
        success = 0;
        goto cleanup;
    }

    if (first->bus_port == 0 || (first->bus_port == first->port + CLUSTER_MANAGER_PORT_INCR)) {
        /* CLUSTER MEET bus-port parameter was added in 4.0.
         * So if (bus_port == 0) or (bus_port == port + CLUSTER_MANAGER_PORT_INCR),
         * we just call CLUSTER MEET with 2 arguments, using the old form. */
        reply = CLUSTER_MANAGER_COMMAND(new_node, "CLUSTER MEET %s %d", first_ip, first->port);
    } else {
        reply = CLUSTER_MANAGER_COMMAND(new_node, "CLUSTER MEET %s %d %d", first_ip, first->port, first->bus_port);
    }

    if (!(success = clusterManagerCheckRedisReply(new_node, reply, NULL))) goto cleanup;

    /* Additional configuration is needed if the node is added as a replica. */
    if (primary_node) {
        sleep(1);
        clusterManagerWaitForClusterJoin();
        clusterManagerLogInfo(">>> Configure node as replica of %s:%d.\n", primary_node->ip, primary_node->port);
        freeReplyObject(reply);
        reply = CLUSTER_MANAGER_COMMAND(new_node, "CLUSTER REPLICATE %s", primary_node->name);
        if (!(success = clusterManagerCheckRedisReply(new_node, reply, NULL))) goto cleanup;
    }
    clusterManagerLogOk("[OK] New node added correctly.\n");
cleanup:
    if (!added && new_node) freeClusterManagerNode(new_node);
    if (reply) freeReplyObject(reply);
    if (function_restore_reply) freeReplyObject(function_restore_reply);
    if (function_list_reply) freeReplyObject(function_list_reply);
    return success;
invalid_args:
    fprintf(stderr, CLUSTER_MANAGER_INVALID_HOST_ARG);
    return 0;
}

static int clusterManagerCommandDeleteNode(int argc, char **argv) {
    UNUSED(argc);
    int success = 1;
    int port = 0;
    char *ip = NULL;
    if (!getClusterHostFromCmdArgs(1, argv, &ip, &port)) goto invalid_args;
    char *node_id = argv[1];
    clusterManagerLogInfo(">>> Removing node %s from cluster %s:%d\n", node_id, ip, port);
    clusterManagerNode *ref_node = clusterManagerNewNode(ip, port, 0);
    clusterManagerNode *node = NULL;

    // Load cluster information
    if (!clusterManagerLoadInfoFromNode(ref_node)) return 0;

    // Check if the node exists and is not empty
    node = clusterManagerNodeByName(node_id);
    if (node == NULL) {
        clusterManagerLogErr("[ERR] No such node ID %s\n", node_id);
        return 0;
    }
    if (node->slots_count != 0) {
        clusterManagerLogErr("[ERR] Node %s:%d is not empty! Reshard data "
                             "away and try again.\n",
                             node->ip, node->port);
        return 0;
    }

    // Send CLUSTER FORGET to all the nodes but the node to remove
    clusterManagerLogInfo(">>> Sending CLUSTER FORGET messages to the "
                          "cluster...\n");
    listIter li;
    listNode *ln;
    listRewind(cluster_manager.nodes, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *n = ln->value;
        if (n == node) continue;
        if (n->replicate && !strcasecmp(n->replicate, node_id)) {
            // Reconfigure the replica to replicate with some other node
            clusterManagerNode *primary = clusterManagerNodeWithLeastReplicas();
            assert(primary != NULL);
            clusterManagerLogInfo(">>> %s:%d as replica of %s:%d\n", n->ip, n->port, primary->ip, primary->port);
            redisReply *r = CLUSTER_MANAGER_COMMAND(n, "CLUSTER REPLICATE %s", primary->name);
            success = clusterManagerCheckRedisReply(n, r, NULL);
            if (r) freeReplyObject(r);
            if (!success) return 0;
        }
        redisReply *r = CLUSTER_MANAGER_COMMAND(n, "CLUSTER FORGET %s", node_id);
        success = clusterManagerCheckRedisReply(n, r, NULL);
        if (r) freeReplyObject(r);
        if (!success) return 0;
    }

    /* Finally send CLUSTER RESET to the node. */
    clusterManagerLogInfo(">>> Sending CLUSTER RESET SOFT to the "
                          "deleted node.\n");
    redisReply *r = redisCommand(node->context, "CLUSTER RESET %s", "SOFT");
    success = clusterManagerCheckRedisReply(node, r, NULL);
    if (r) freeReplyObject(r);
    return success;
invalid_args:
    fprintf(stderr, CLUSTER_MANAGER_INVALID_HOST_ARG);
    return 0;
}

static int clusterManagerCommandInfo(int argc, char **argv) {
    int port = 0;
    char *ip = NULL;
    if (!getClusterHostFromCmdArgs(argc, argv, &ip, &port)) goto invalid_args;
    clusterManagerNode *node = clusterManagerNewNode(ip, port, 0);
    if (!clusterManagerLoadInfoFromNode(node)) return 0;
    clusterManagerShowClusterInfo();
    return 1;
invalid_args:
    fprintf(stderr, CLUSTER_MANAGER_INVALID_HOST_ARG);
    return 0;
}

static int clusterManagerCommandCheck(int argc, char **argv) {
    int port = 0;
    char *ip = NULL;
    if (!getClusterHostFromCmdArgs(argc, argv, &ip, &port)) goto invalid_args;
    clusterManagerNode *node = clusterManagerNewNode(ip, port, 0);
    if (!clusterManagerLoadInfoFromNode(node)) return 0;
    clusterManagerShowClusterInfo();
    return clusterManagerCheckCluster(0);
invalid_args:
    fprintf(stderr, CLUSTER_MANAGER_INVALID_HOST_ARG);
    return 0;
}

static int clusterManagerCommandFix(int argc, char **argv) {
    config.cluster_manager_command.flags |= CLUSTER_MANAGER_CMD_FLAG_FIX;
    return clusterManagerCommandCheck(argc, argv);
}

static int clusterManagerCommandReshard(int argc, char **argv) {
    int port = 0;
    char *ip = NULL;
    if (!getClusterHostFromCmdArgs(argc, argv, &ip, &port)) goto invalid_args;
    clusterManagerNode *node = clusterManagerNewNode(ip, port, 0);
    if (!clusterManagerLoadInfoFromNode(node)) return 0;
    clusterManagerCheckCluster(0);
    if (cluster_manager.errors && listLength(cluster_manager.errors) > 0) {
        fflush(stdout);
        fprintf(stderr, "*** Please fix your cluster problems before resharding\n");
        return 0;
    }
    int slots = config.cluster_manager_command.slots;
    if (!slots) {
        while (slots <= 0 || slots > CLUSTER_MANAGER_SLOTS) {
            printf("How many slots do you want to move (from 1 to %d)? ", CLUSTER_MANAGER_SLOTS);
            fflush(stdout);
            char buf[6];
            int nread = read(fileno(stdin), buf, 6);
            if (nread <= 0) continue;
            int last_idx = nread - 1;
            if (buf[last_idx] != '\n') {
                int ch;
                while ((ch = getchar()) != '\n' && ch != EOF) {
                }
            }
            buf[last_idx] = '\0';
            slots = atoi(buf);
        }
    }
    char buf[255];
    char *to = config.cluster_manager_command.to, *from = config.cluster_manager_command.from;
    while (to == NULL) {
        printf("What is the receiving node ID? ");
        fflush(stdout);
        int nread = read(fileno(stdin), buf, 255);
        if (nread <= 0) continue;
        int last_idx = nread - 1;
        if (buf[last_idx] != '\n') {
            int ch;
            while ((ch = getchar()) != '\n' && ch != EOF) {
            }
        }
        buf[last_idx] = '\0';
        if (strlen(buf) > 0) to = buf;
    }
    int raise_err = 0;
    clusterManagerNode *target = clusterNodeForResharding(to, NULL, &raise_err);
    if (target == NULL) return 0;
    list *sources = listCreate();
    list *table = NULL;
    int all = 0, result = 1;
    if (from == NULL) {
        printf("Please enter all the source node IDs.\n");
        printf("  Type 'all' to use all the nodes as source nodes for "
               "the hash slots.\n");
        printf("  Type 'done' once you entered all the source nodes IDs.\n");
        while (1) {
            printf("Source node #%lu: ", listLength(sources) + 1);
            fflush(stdout);
            int nread = read(fileno(stdin), buf, 255);
            if (nread <= 0) continue;
            int last_idx = nread - 1;
            if (buf[last_idx] != '\n') {
                int ch;
                while ((ch = getchar()) != '\n' && ch != EOF) {
                }
            }
            buf[last_idx] = '\0';
            if (!strcmp(buf, "done"))
                break;
            else if (!strcmp(buf, "all")) {
                all = 1;
                break;
            } else {
                clusterManagerNode *src = clusterNodeForResharding(buf, target, &raise_err);
                if (src != NULL)
                    listAddNodeTail(sources, src);
                else if (raise_err) {
                    result = 0;
                    goto cleanup;
                }
            }
        }
    } else {
        char *p;
        while ((p = strchr(from, ',')) != NULL) {
            *p = '\0';
            if (!strcmp(from, "all")) {
                all = 1;
                break;
            } else {
                clusterManagerNode *src = clusterNodeForResharding(from, target, &raise_err);
                if (src != NULL)
                    listAddNodeTail(sources, src);
                else if (raise_err) {
                    result = 0;
                    goto cleanup;
                }
            }
            from = p + 1;
        }
        /* Check if there's still another source to process. */
        if (!all && strlen(from) > 0) {
            if (!strcmp(from, "all")) all = 1;
            if (!all) {
                clusterManagerNode *src = clusterNodeForResharding(from, target, &raise_err);
                if (src != NULL)
                    listAddNodeTail(sources, src);
                else if (raise_err) {
                    result = 0;
                    goto cleanup;
                }
            }
        }
    }
    listIter li;
    listNode *ln;
    if (all) {
        listEmpty(sources);
        listRewind(cluster_manager.nodes, &li);
        while ((ln = listNext(&li)) != NULL) {
            clusterManagerNode *n = ln->value;
            if (n->flags & CLUSTER_MANAGER_FLAG_REPLICA || n->replicate) continue;
            if (!sdscmp(n->name, target->name)) continue;
            listAddNodeTail(sources, n);
        }
    }
    if (listLength(sources) == 0) {
        fprintf(stderr, "*** No source nodes given, operation aborted.\n");
        result = 0;
        goto cleanup;
    }
    printf("\nReady to move %d slots.\n", slots);
    printf("  Source nodes:\n");
    listRewind(sources, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *src = ln->value;
        sds info = clusterManagerNodeInfo(src, 4);
        printf("%s\n", info);
        sdsfree(info);
    }
    printf("  Destination node:\n");
    sds info = clusterManagerNodeInfo(target, 4);
    printf("%s\n", info);
    sdsfree(info);
    table = clusterManagerComputeReshardTable(sources, slots);
    printf("  Resharding plan:\n");
    clusterManagerShowReshardTable(table);
    if (!(config.cluster_manager_command.flags & CLUSTER_MANAGER_CMD_FLAG_YES)) {
        printf("Do you want to proceed with the proposed "
               "reshard plan (yes/no)? ");
        fflush(stdout);
        char buf[4];
        int nread = read(fileno(stdin), buf, 4);
        buf[3] = '\0';
        if (nread <= 0 || strcmp("yes", buf) != 0) {
            result = 0;
            goto cleanup;
        }
    }
    int opts = CLUSTER_MANAGER_OPT_VERBOSE;
    listRewind(table, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerReshardTableItem *item = ln->value;
        char *err = NULL;
        result = clusterManagerMoveSlot(item->source, target, item->slot, opts, &err);
        if (!result) {
            if (err != NULL) {
                clusterManagerLogErr("clusterManagerMoveSlot failed: %s\n", err);
                zfree(err);
            }
            goto cleanup;
        }
    }
cleanup:
    listRelease(sources);
    clusterManagerReleaseReshardTable(table);
    return result;
invalid_args:
    fprintf(stderr, CLUSTER_MANAGER_INVALID_HOST_ARG);
    return 0;
}

static int clusterManagerCommandRebalance(int argc, char **argv) {
    int port = 0;
    char *ip = NULL;
    clusterManagerNode **weightedNodes = NULL;
    list *involved = NULL;
    if (!getClusterHostFromCmdArgs(argc, argv, &ip, &port)) goto invalid_args;
    clusterManagerNode *node = clusterManagerNewNode(ip, port, 0);
    if (!clusterManagerLoadInfoFromNode(node)) return 0;
    int result = 1, i;
    if (config.cluster_manager_command.weight != NULL) {
        for (i = 0; i < config.cluster_manager_command.weight_argc; i++) {
            char *name = config.cluster_manager_command.weight[i];
            char *p = strchr(name, '=');
            if (p == NULL) {
                clusterManagerLogErr("*** invalid input %s\n", name);
                result = 0;
                goto cleanup;
            }
            *p = '\0';
            float w = atof(++p);
            clusterManagerNode *n = clusterManagerNodeByAbbreviatedName(name);
            if (n == NULL) {
                clusterManagerLogErr("*** No such primary node %s\n", name);
                result = 0;
                goto cleanup;
            }
            n->weight = w;
        }
    }
    float total_weight = 0;
    int nodes_involved = 0;
    int use_empty = config.cluster_manager_command.flags & CLUSTER_MANAGER_CMD_FLAG_EMPTY_PRIMARY;
    involved = listCreate();
    listIter li;
    listNode *ln;
    listRewind(cluster_manager.nodes, &li);
    /* Compute the total cluster weight. */
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *n = ln->value;
        if (n->flags & CLUSTER_MANAGER_FLAG_REPLICA || n->replicate) continue;
        if (!use_empty && n->slots_count == 0) {
            n->weight = 0;
            continue;
        }
        total_weight += n->weight;
        nodes_involved++;
        listAddNodeTail(involved, n);
    }
    weightedNodes = zmalloc(nodes_involved * sizeof(clusterManagerNode *));
    if (weightedNodes == NULL) goto cleanup;
    /* Check cluster, only proceed if it looks sane. */
    clusterManagerCheckCluster(1);
    if (cluster_manager.errors && listLength(cluster_manager.errors) > 0) {
        clusterManagerLogErr("*** Please fix your cluster problems "
                             "before rebalancing\n");
        result = 0;
        goto cleanup;
    }
    /* Calculate the slots balance for each node. It's the number of
     * slots the node should lose (if positive) or gain (if negative)
     * in order to be balanced. */
    int threshold_reached = 0, total_balance = 0;
    float threshold = config.cluster_manager_command.threshold;
    i = 0;
    listRewind(involved, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *n = ln->value;
        weightedNodes[i++] = n;
        int expected = (int)(((float)CLUSTER_MANAGER_SLOTS / total_weight) * n->weight);
        n->balance = n->slots_count - expected;
        total_balance += n->balance;
        /* Compute the percentage of difference between the
         * expected number of slots and the real one, to see
         * if it's over the threshold specified by the user. */
        int over_threshold = 0;
        if (threshold > 0) {
            if (n->slots_count > 0) {
                float err_perc = fabs((100 - (100.0 * expected / n->slots_count)));
                if (err_perc > threshold) over_threshold = 1;
            } else if (expected > 1) {
                over_threshold = 1;
            }
        }
        if (over_threshold) threshold_reached = 1;
    }
    if (!threshold_reached) {
        clusterManagerLogWarn("*** No rebalancing needed! "
                              "All nodes are within the %.2f%% threshold.\n",
                              config.cluster_manager_command.threshold);
        goto cleanup;
    }
    /* Because of rounding, it is possible that the balance of all nodes
     * summed does not give 0. Make sure that nodes that have to provide
     * slots are always matched by nodes receiving slots. */
    while (total_balance > 0) {
        listRewind(involved, &li);
        while ((ln = listNext(&li)) != NULL) {
            clusterManagerNode *n = ln->value;
            if (n->balance <= 0 && total_balance > 0) {
                n->balance--;
                total_balance--;
            }
        }
    }
    /* Sort nodes by their slots balance. */
    qsort(weightedNodes, nodes_involved, sizeof(clusterManagerNode *), clusterManagerCompareNodeBalance);
    clusterManagerLogInfo(">>> Rebalancing across %d nodes. "
                          "Total weight = %.2f\n",
                          nodes_involved, total_weight);
    if (config.verbose) {
        for (i = 0; i < nodes_involved; i++) {
            clusterManagerNode *n = weightedNodes[i];
            printf("%s:%d balance is %d slots\n", n->ip, n->port, n->balance);
        }
    }
    /* Now we have at the start of the 'sn' array nodes that should get
     * slots, at the end nodes that must give slots.
     * We take two indexes, one at the start, and one at the end,
     * incrementing or decrementing the indexes accordingly til we
     * find nodes that need to get/provide slots. */
    int dst_idx = 0;
    int src_idx = nodes_involved - 1;
    int simulate = config.cluster_manager_command.flags & CLUSTER_MANAGER_CMD_FLAG_SIMULATE;
    while (dst_idx < src_idx) {
        clusterManagerNode *dst = weightedNodes[dst_idx];
        clusterManagerNode *src = weightedNodes[src_idx];
        int db = abs(dst->balance);
        int sb = abs(src->balance);
        int numslots = (db < sb ? db : sb);
        if (numslots > 0) {
            printf("Moving %d slots from %s:%d to %s:%d\n", numslots, src->ip, src->port, dst->ip, dst->port);
            /* Actually move the slots. */
            list *lsrc = listCreate(), *table = NULL;
            listAddNodeTail(lsrc, src);
            table = clusterManagerComputeReshardTable(lsrc, numslots);
            listRelease(lsrc);
            int table_len = (int)listLength(table);
            if (!table || table_len != numslots) {
                clusterManagerLogErr("*** Assertion failed: Reshard table "
                                     "!= number of slots");
                result = 0;
                goto end_move;
            }
            if (simulate) {
                for (i = 0; i < table_len; i++) printf("#");
            } else {
                int opts = CLUSTER_MANAGER_OPT_QUIET | CLUSTER_MANAGER_OPT_UPDATE;
                listRewind(table, &li);
                while ((ln = listNext(&li)) != NULL) {
                    clusterManagerReshardTableItem *item = ln->value;
                    char *err;
                    result = clusterManagerMoveSlot(item->source, dst, item->slot, opts, &err);
                    if (!result) {
                        clusterManagerLogErr("*** clusterManagerMoveSlot: %s\n", err);
                        zfree(err);
                        goto end_move;
                    }
                    printf("#");
                    fflush(stdout);
                }
            }
            printf("\n");
        end_move:
            clusterManagerReleaseReshardTable(table);
            if (!result) goto cleanup;
        }
        /* Update nodes balance. */
        dst->balance += numslots;
        src->balance -= numslots;
        if (dst->balance == 0) dst_idx++;
        if (src->balance == 0) src_idx--;
    }
cleanup:
    if (involved != NULL) listRelease(involved);
    if (weightedNodes != NULL) zfree(weightedNodes);
    return result;
invalid_args:
    fprintf(stderr, CLUSTER_MANAGER_INVALID_HOST_ARG);
    return 0;
}

static int clusterManagerCommandSetTimeout(int argc, char **argv) {
    UNUSED(argc);
    int port = 0;
    char *ip = NULL;
    if (!getClusterHostFromCmdArgs(1, argv, &ip, &port)) goto invalid_args;
    int timeout = atoi(argv[1]);
    if (timeout < 100) {
        fprintf(stderr, "Setting a node timeout of less than 100 "
                        "milliseconds is a bad idea.\n");
        return 0;
    }
    // Load cluster information
    clusterManagerNode *node = clusterManagerNewNode(ip, port, 0);
    if (!clusterManagerLoadInfoFromNode(node)) return 0;
    int ok_count = 0, err_count = 0;

    clusterManagerLogInfo(">>> Reconfiguring node timeout in every "
                          "cluster node...\n");
    listIter li;
    listNode *ln;
    listRewind(cluster_manager.nodes, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *n = ln->value;
        char *err = NULL;
        redisReply *reply = CLUSTER_MANAGER_COMMAND(n, "CONFIG %s %s %d", "SET", "cluster-node-timeout", timeout);
        if (reply == NULL) goto reply_err;
        int ok = clusterManagerCheckRedisReply(n, reply, &err);
        freeReplyObject(reply);
        if (!ok) goto reply_err;
        reply = CLUSTER_MANAGER_COMMAND(n, "CONFIG %s", "REWRITE");
        if (reply == NULL) goto reply_err;
        ok = clusterManagerCheckRedisReply(n, reply, &err);
        freeReplyObject(reply);
        if (!ok) goto reply_err;
        clusterManagerLogWarn("*** New timeout set for %s:%d\n", n->ip, n->port);
        ok_count++;
        continue;
    reply_err:;
        int need_free = 0;
        if (err == NULL)
            err = "";
        else
            need_free = 1;
        clusterManagerLogErr("ERR setting node-timeout for %s:%d: %s\n", n->ip, n->port, err);
        if (need_free) zfree(err);
        err_count++;
    }
    clusterManagerLogInfo(">>> New node timeout set. %d OK, %d ERR.\n", ok_count, err_count);
    return 1;
invalid_args:
    fprintf(stderr, CLUSTER_MANAGER_INVALID_HOST_ARG);
    return 0;
}

static int clusterManagerCommandImport(int argc, char **argv) {
    int success = 1;
    int port = 0, src_port = 0;
    char *ip = NULL, *src_ip = NULL;
    char *invalid_args_msg = NULL;
    sds cmdfmt = NULL;
    if (!getClusterHostFromCmdArgs(argc, argv, &ip, &port)) {
        invalid_args_msg = CLUSTER_MANAGER_INVALID_HOST_ARG;
        goto invalid_args;
    }
    if (config.cluster_manager_command.from == NULL) {
        invalid_args_msg = "[ERR] Option '--cluster-from' is required for "
                           "subcommand 'import'.\n";
        goto invalid_args;
    }
    char *src_host[] = {config.cluster_manager_command.from};
    if (!getClusterHostFromCmdArgs(1, src_host, &src_ip, &src_port)) {
        invalid_args_msg = "[ERR] Invalid --cluster-from host. You need to "
                           "pass a valid address (ie. 120.0.0.1:7000).\n";
        goto invalid_args;
    }
    clusterManagerLogInfo(">>> Importing data from %s:%d to cluster %s:%d\n", src_ip, src_port, ip, port);

    clusterManagerNode *refnode = clusterManagerNewNode(ip, port, 0);
    if (!clusterManagerLoadInfoFromNode(refnode)) return 0;
    if (!clusterManagerCheckCluster(0)) return 0;
    char *reply_err = NULL;
    redisReply *src_reply = NULL;
    // Connect to the source node.
    redisContext *src_ctx = redisConnectWrapper(src_ip, src_port, config.connect_timeout);
    if (src_ctx->err) {
        success = 0;
        fprintf(stderr, "Could not connect to Valkey at %s:%d: %s.\n", src_ip, src_port, src_ctx->errstr);
        goto cleanup;
    }
    // Auth for the source node.
    char *from_user = config.cluster_manager_command.from_user;
    char *from_pass = config.cluster_manager_command.from_pass;
    if (cliAuth(src_ctx, from_user, from_pass) == REDIS_ERR) {
        success = 0;
        goto cleanup;
    }

    src_reply = reconnectingRedisCommand(src_ctx, "INFO");
    if (!src_reply || src_reply->type == REDIS_REPLY_ERROR) {
        if (src_reply && src_reply->str) reply_err = src_reply->str;
        success = 0;
        goto cleanup;
    }
    if (getLongInfoField(src_reply->str, "cluster_enabled")) {
        clusterManagerLogErr("[ERR] The source node should not be a "
                             "cluster node.\n");
        success = 0;
        goto cleanup;
    }
    freeReplyObject(src_reply);
    src_reply = reconnectingRedisCommand(src_ctx, "DBSIZE");
    if (!src_reply || src_reply->type == REDIS_REPLY_ERROR) {
        if (src_reply && src_reply->str) reply_err = src_reply->str;
        success = 0;
        goto cleanup;
    }
    int size = src_reply->integer, i;
    clusterManagerLogWarn("*** Importing %d keys from DB 0\n", size);

    // Build a slot -> node map
    clusterManagerNode *slots_map[CLUSTER_MANAGER_SLOTS];
    memset(slots_map, 0, sizeof(slots_map));
    listIter li;
    listNode *ln;
    for (i = 0; i < CLUSTER_MANAGER_SLOTS; i++) {
        listRewind(cluster_manager.nodes, &li);
        while ((ln = listNext(&li)) != NULL) {
            clusterManagerNode *n = ln->value;
            if (n->flags & CLUSTER_MANAGER_FLAG_REPLICA) continue;
            if (n->slots_count == 0) continue;
            if (n->slots[i]) {
                slots_map[i] = n;
                break;
            }
        }
    }
    cmdfmt = sdsnew("MIGRATE %s %d %s %d %d");
    if (config.conn_info.auth) {
        if (config.conn_info.user) {
            cmdfmt = sdscatfmt(cmdfmt, " AUTH2 %s %s", config.conn_info.user, config.conn_info.auth);
        } else {
            cmdfmt = sdscatfmt(cmdfmt, " AUTH %s", config.conn_info.auth);
        }
    }

    if (config.cluster_manager_command.flags & CLUSTER_MANAGER_CMD_FLAG_COPY) cmdfmt = sdscat(cmdfmt, " COPY");
    if (config.cluster_manager_command.flags & CLUSTER_MANAGER_CMD_FLAG_REPLACE) cmdfmt = sdscat(cmdfmt, " REPLACE");

    /* Use SCAN to iterate over the keys, migrating to the
     * right node as needed. */
    int cursor = -999, timeout = config.cluster_manager_command.timeout;
    while (cursor != 0) {
        if (cursor < 0) cursor = 0;
        freeReplyObject(src_reply);
        src_reply = reconnectingRedisCommand(src_ctx, "SCAN %d COUNT %d", cursor, 1000);
        if (!src_reply || src_reply->type == REDIS_REPLY_ERROR) {
            if (src_reply && src_reply->str) reply_err = src_reply->str;
            success = 0;
            goto cleanup;
        }
        assert(src_reply->type == REDIS_REPLY_ARRAY);
        assert(src_reply->elements >= 2);
        assert(src_reply->element[1]->type == REDIS_REPLY_ARRAY);
        if (src_reply->element[0]->type == REDIS_REPLY_STRING)
            cursor = atoi(src_reply->element[0]->str);
        else if (src_reply->element[0]->type == REDIS_REPLY_INTEGER)
            cursor = src_reply->element[0]->integer;
        int keycount = src_reply->element[1]->elements;
        for (i = 0; i < keycount; i++) {
            redisReply *kr = src_reply->element[1]->element[i];
            assert(kr->type == REDIS_REPLY_STRING);
            char *key = kr->str;
            uint16_t slot = clusterManagerKeyHashSlot(key, kr->len);
            clusterManagerNode *target = slots_map[slot];
            printf("Migrating %s to %s:%d: ", key, target->ip, target->port);
            redisReply *r = reconnectingRedisCommand(src_ctx, cmdfmt, target->ip, target->port, key, 0, timeout);
            if (!r || r->type == REDIS_REPLY_ERROR) {
                if (r && r->str) {
                    clusterManagerLogErr("Source %s:%d replied with "
                                         "error:\n%s\n",
                                         src_ip, src_port, r->str);
                }
                success = 0;
            }
            freeReplyObject(r);
            if (!success) goto cleanup;
            clusterManagerLogOk("OK\n");
        }
    }
cleanup:
    if (reply_err) clusterManagerLogErr("Source %s:%d replied with error:\n%s\n", src_ip, src_port, reply_err);
    if (src_ctx) redisFree(src_ctx);
    if (src_reply) freeReplyObject(src_reply);
    if (cmdfmt) sdsfree(cmdfmt);
    return success;
invalid_args:
    fprintf(stderr, "%s", invalid_args_msg);
    return 0;
}

static int clusterManagerCommandCall(int argc, char **argv) {
    int port = 0, i;
    char *ip = NULL;
    if (!getClusterHostFromCmdArgs(1, argv, &ip, &port)) goto invalid_args;
    clusterManagerNode *refnode = clusterManagerNewNode(ip, port, 0);
    if (!clusterManagerLoadInfoFromNode(refnode)) return 0;
    argc--;
    argv++;
    size_t *argvlen = zmalloc(argc * sizeof(size_t));
    clusterManagerLogInfo(">>> Calling");
    for (i = 0; i < argc; i++) {
        argvlen[i] = strlen(argv[i]);
        printf(" %s", argv[i]);
    }
    printf("\n");
    listIter li;
    listNode *ln;
    listRewind(cluster_manager.nodes, &li);
    while ((ln = listNext(&li)) != NULL) {
        clusterManagerNode *n = ln->value;
        if ((config.cluster_manager_command.flags & CLUSTER_MANAGER_CMD_FLAG_PRIMARIES_ONLY) && (n->replicate != NULL))
            continue; // continue if node is replica
        if ((config.cluster_manager_command.flags & CLUSTER_MANAGER_CMD_FLAG_REPLICAS_ONLY) && (n->replicate == NULL))
            continue; // continue if node is primary
        if (!n->context && !clusterManagerNodeConnect(n)) continue;
        redisReply *reply = NULL;
        redisAppendCommandArgv(n->context, argc, (const char **)argv, argvlen);
        int status = redisGetReply(n->context, (void **)(&reply));
        if (status != REDIS_OK || reply == NULL)
            printf("%s:%d: Failed!\n", n->ip, n->port);
        else {
            sds formatted_reply = cliFormatReplyRaw(reply);
            printf("%s:%d: %s\n", n->ip, n->port, (char *)formatted_reply);
            sdsfree(formatted_reply);
        }
        if (reply != NULL) freeReplyObject(reply);
    }
    zfree(argvlen);
    return 1;
invalid_args:
    fprintf(stderr, CLUSTER_MANAGER_INVALID_HOST_ARG);
    return 0;
}

static int clusterManagerCommandBackup(int argc, char **argv) {
    UNUSED(argc);
    int success = 1, port = 0;
    char *ip = NULL;
    if (!getClusterHostFromCmdArgs(1, argv, &ip, &port)) goto invalid_args;
    clusterManagerNode *refnode = clusterManagerNewNode(ip, port, 0);
    if (!clusterManagerLoadInfoFromNode(refnode)) return 0;
    int no_issues = clusterManagerCheckCluster(0);
    int cluster_errors_count = (no_issues ? 0 : listLength(cluster_manager.errors));
    config.cluster_manager_command.backup_dir = argv[1];
    /* TODO: check if backup_dir is a valid directory. */
    sds json = sdsnew("[\n");
    int first_node = 0;
    listIter li;
    listNode *ln;
    listRewind(cluster_manager.nodes, &li);
    while ((ln = listNext(&li)) != NULL) {
        if (!first_node)
            first_node = 1;
        else
            json = sdscat(json, ",\n");
        clusterManagerNode *node = ln->value;
        sds node_json = clusterManagerNodeGetJSON(node, cluster_errors_count);
        json = sdscat(json, node_json);
        sdsfree(node_json);
        if (node->replicate) continue;
        clusterManagerLogInfo(">>> Node %s:%d -> Saving RDB...\n", node->ip, node->port);
        fflush(stdout);
        getRDB(node);
    }
    json = sdscat(json, "\n]");
    sds jsonpath = sdsnew(config.cluster_manager_command.backup_dir);
    if (jsonpath[sdslen(jsonpath) - 1] != '/') jsonpath = sdscat(jsonpath, "/");
    jsonpath = sdscat(jsonpath, "nodes.json");
    fflush(stdout);
    clusterManagerLogInfo("Saving cluster configuration to: %s\n", jsonpath);
    FILE *out = fopen(jsonpath, "w+");
    if (!out) {
        clusterManagerLogErr("Could not save nodes to: %s\n", jsonpath);
        success = 0;
        goto cleanup;
    }
    fputs(json, out);
    fclose(out);
cleanup:
    sdsfree(json);
    sdsfree(jsonpath);
    if (success) {
        if (!no_issues) {
            clusterManagerLogWarn("*** Cluster seems to have some problems, "
                                  "please be aware of it if you're going "
                                  "to restore this backup.\n");
        }
        clusterManagerLogOk("[OK] Backup created into: %s\n", config.cluster_manager_command.backup_dir);
    } else
        clusterManagerLogOk("[ERR] Failed to back cluster!\n");
    return success;
invalid_args:
    fprintf(stderr, CLUSTER_MANAGER_INVALID_HOST_ARG);
    return 0;
}

static int clusterManagerCommandHelp(int argc, char **argv) {
    UNUSED(argc);
    UNUSED(argv);
    int commands_count = sizeof(clusterManagerCommands) / sizeof(clusterManagerCommandDef);
    int i = 0, j;
    fprintf(stdout, "Cluster Manager Commands:\n");
    int padding = 15;
    for (; i < commands_count; i++) {
        clusterManagerCommandDef *def = &(clusterManagerCommands[i]);
        int namelen = strlen(def->name), padlen = padding - namelen;
        fprintf(stdout, "  %s", def->name);
        for (j = 0; j < padlen; j++) fprintf(stdout, " ");
        fprintf(stdout, "%s\n", (def->args ? def->args : ""));
        if (def->options != NULL) {
            int optslen = strlen(def->options);
            char *p = def->options, *eos = p + optslen;
            char *comma = NULL;
            while ((comma = strchr(p, ',')) != NULL) {
                int deflen = (int)(comma - p);
                char buf[255];
                memcpy(buf, p, deflen);
                buf[deflen] = '\0';
                for (j = 0; j < padding; j++) fprintf(stdout, " ");
                fprintf(stdout, "  --cluster-%s\n", buf);
                p = comma + 1;
                if (p >= eos) break;
            }
            if (p < eos) {
                for (j = 0; j < padding; j++) fprintf(stdout, " ");
                fprintf(stdout, "  --cluster-%s\n", p);
            }
        }
    }
    fprintf(stdout, "\nFor check, fix, reshard, del-node, set-timeout, "
                    "info, rebalance, call, import, backup you "
                    "can specify the host and port of any working node in "
                    "the cluster.\n");

    int options_count = sizeof(clusterManagerOptions) / sizeof(clusterManagerOptionDef);
    i = 0;
    fprintf(stdout, "\nCluster Manager Options:\n");
    for (; i < options_count; i++) {
        clusterManagerOptionDef *def = &(clusterManagerOptions[i]);
        int namelen = strlen(def->name), padlen = padding - namelen;
        fprintf(stdout, "  %s", def->name);
        for (j = 0; j < padlen; j++) fprintf(stdout, " ");
        fprintf(stdout, "%s\n", def->desc);
    }

    fprintf(stdout, "\n");
    return 0;
}

/*------------------------------------------------------------------------------
 * Latency and latency history modes
 *--------------------------------------------------------------------------- */

static void latencyModePrint(long long min, long long max, double avg, long long count) {
    if (config.output == OUTPUT_STANDARD) {
        printf("min: %lld, max: %lld, avg: %.2f (%lld samples)", min, max, avg, count);
        fflush(stdout);
    } else if (config.output == OUTPUT_CSV) {
        printf("%lld,%lld,%.2f,%lld\n", min, max, avg, count);
    } else if (config.output == OUTPUT_RAW) {
        printf("%lld %lld %.2f %lld\n", min, max, avg, count);
    } else if (config.output == OUTPUT_JSON) {
        printf("{\"min\": %lld, \"max\": %lld, \"avg\": %.2f, \"count\": %lld}\n", min, max, avg, count);
    }
}

#define LATENCY_SAMPLE_RATE 10                 /* milliseconds. */
#define LATENCY_HISTORY_DEFAULT_INTERVAL 15000 /* milliseconds. */
static void latencyMode(void) {
    redisReply *reply;
    long long start, latency, min = 0, max = 0, tot = 0, count = 0;
    long long history_interval = config.interval ? config.interval / 1000 : LATENCY_HISTORY_DEFAULT_INTERVAL;
    double avg;
    long long history_start = mstime();

    /* Set a default for the interval in case of --latency option
     * with --raw, --csv or when it is redirected to non tty. */
    if (config.interval == 0) {
        config.interval = 1000;
    } else {
        config.interval /= 1000; /* We need to convert to milliseconds. */
    }

    if (!context) exit(1);
    while (1) {
        start = mstime();
        reply = reconnectingRedisCommand(context, "PING");
        if (reply == NULL) {
            fprintf(stderr, "\nI/O error\n");
            exit(1);
        }
        latency = mstime() - start;
        freeReplyObject(reply);
        count++;
        if (count == 1) {
            min = max = tot = latency;
            avg = (double)latency;
        } else {
            if (latency < min) min = latency;
            if (latency > max) max = latency;
            tot += latency;
            avg = (double)tot / count;
        }

        if (config.output == OUTPUT_STANDARD) {
            printf("\x1b[0G\x1b[2K"); /* Clear the line. */
            latencyModePrint(min, max, avg, count);
        } else {
            if (config.latency_history) {
                latencyModePrint(min, max, avg, count);
            } else if (mstime() - history_start > config.interval) {
                latencyModePrint(min, max, avg, count);
                exit(0);
            }
        }

        if (config.latency_history && mstime() - history_start > history_interval) {
            printf(" -- %.2f seconds range\n", (float)(mstime() - history_start) / 1000);
            history_start = mstime();
            min = max = tot = count = 0;
        }
        usleep(LATENCY_SAMPLE_RATE * 1000);
    }
}

/*------------------------------------------------------------------------------
 * Latency distribution mode -- requires 256 colors xterm
 *--------------------------------------------------------------------------- */

#define LATENCY_DIST_DEFAULT_INTERVAL 1000 /* milliseconds. */

/* Structure to store samples distribution. */
struct distsamples {
    long long max;   /* Max latency to fit into this interval (usec). */
    long long count; /* Number of samples in this interval. */
    int character;   /* Associated character in visualization. */
};

/* Helper function for latencyDistMode(). Performs the spectrum visualization
 * of the collected samples targeting an xterm 256 terminal.
 *
 * Takes an array of distsamples structures, ordered from smaller to bigger
 * 'max' value. Last sample max must be 0, to mean that it holds all the
 * samples greater than the previous one, and is also the stop sentinel.
 *
 * "tot' is the total number of samples in the different buckets, so it
 * is the SUM(samples[i].count) for i to 0 up to the max sample.
 *
 * As a side effect the function sets all the buckets count to 0. */
void showLatencyDistSamples(struct distsamples *samples, long long tot) {
    int j;

    /* We convert samples into an index inside the palette
     * proportional to the percentage a given bucket represents.
     * This way intensity of the different parts of the spectrum
     * don't change relative to the number of requests, which avoids to
     * pollute the visualization with non-latency related info. */
    printf("\033[38;5;0m"); /* Set foreground color to black. */
    for (j = 0;; j++) {
        int coloridx = ceil((double)samples[j].count / tot * (spectrum_palette_size - 1));
        int color = spectrum_palette[coloridx];
        printf("\033[48;5;%dm%c", (int)color, samples[j].character);
        samples[j].count = 0;
        if (samples[j].max == 0) break; /* Last sample. */
    }
    printf("\033[0m\n");
    fflush(stdout);
}

/* Show the legend: different buckets values and colors meaning, so
 * that the spectrum is more easily readable. */
void showLatencyDistLegend(void) {
    int j;

    printf("---------------------------------------------\n");
    printf(". - * #          .01 .125 .25 .5 milliseconds\n");
    printf("1,2,3,...,9      from 1 to 9     milliseconds\n");
    printf("A,B,C,D,E        10,20,30,40,50  milliseconds\n");
    printf("F,G,H,I,J        .1,.2,.3,.4,.5       seconds\n");
    printf("K,L,M,N,O,P,Q,?  1,2,4,8,16,30,60,>60 seconds\n");
    printf("From 0 to 100%%: ");
    for (j = 0; j < spectrum_palette_size; j++) {
        printf("\033[48;5;%dm ", spectrum_palette[j]);
    }
    printf("\033[0m\n");
    printf("---------------------------------------------\n");
}

static void latencyDistMode(void) {
    redisReply *reply;
    long long start, latency, count = 0;
    long long history_interval = config.interval ? config.interval / 1000 : LATENCY_DIST_DEFAULT_INTERVAL;
    long long history_start = ustime();
    int j, outputs = 0;

    struct distsamples samples[] = {
        /* We use a mostly logarithmic scale, with certain linear intervals
         * which are more interesting than others, like 1-10 milliseconds
         * range. */
        {10, 0, '.'},       /* 0.01 ms */
        {125, 0, '-'},      /* 0.125 ms */
        {250, 0, '*'},      /* 0.25 ms */
        {500, 0, '#'},      /* 0.5 ms */
        {1000, 0, '1'},     /* 1 ms */
        {2000, 0, '2'},     /* 2 ms */
        {3000, 0, '3'},     /* 3 ms */
        {4000, 0, '4'},     /* 4 ms */
        {5000, 0, '5'},     /* 5 ms */
        {6000, 0, '6'},     /* 6 ms */
        {7000, 0, '7'},     /* 7 ms */
        {8000, 0, '8'},     /* 8 ms */
        {9000, 0, '9'},     /* 9 ms */
        {10000, 0, 'A'},    /* 10 ms */
        {20000, 0, 'B'},    /* 20 ms */
        {30000, 0, 'C'},    /* 30 ms */
        {40000, 0, 'D'},    /* 40 ms */
        {50000, 0, 'E'},    /* 50 ms */
        {100000, 0, 'F'},   /* 0.1 s */
        {200000, 0, 'G'},   /* 0.2 s */
        {300000, 0, 'H'},   /* 0.3 s */
        {400000, 0, 'I'},   /* 0.4 s */
        {500000, 0, 'J'},   /* 0.5 s */
        {1000000, 0, 'K'},  /* 1 s */
        {2000000, 0, 'L'},  /* 2 s */
        {4000000, 0, 'M'},  /* 4 s */
        {8000000, 0, 'N'},  /* 8 s */
        {16000000, 0, 'O'}, /* 16 s */
        {30000000, 0, 'P'}, /* 30 s */
        {60000000, 0, 'Q'}, /* 1 minute */
        {0, 0, '?'},        /* > 1 minute */
    };

    if (!context) exit(1);
    while (1) {
        start = ustime();
        reply = reconnectingRedisCommand(context, "PING");
        if (reply == NULL) {
            fprintf(stderr, "\nI/O error\n");
            exit(1);
        }
        latency = ustime() - start;
        freeReplyObject(reply);
        count++;

        /* Populate the relevant bucket. */
        for (j = 0;; j++) {
            if (samples[j].max == 0 || latency <= samples[j].max) {
                samples[j].count++;
                break;
            }
        }

        /* From time to time show the spectrum. */
        if (count && (ustime() - history_start) / 1000 > history_interval) {
            if ((outputs++ % 20) == 0) showLatencyDistLegend();
            showLatencyDistSamples(samples, count);
            history_start = ustime();
            count = 0;
        }
        usleep(LATENCY_SAMPLE_RATE * 1000);
    }
}

/*------------------------------------------------------------------------------
 * Replica mode
 *--------------------------------------------------------------------------- */

#define RDB_EOF_MARK_SIZE 40

int sendReplconf(const char *arg1, const char *arg2) {
    int res = 1;
    fprintf(stderr, "sending REPLCONF %s %s\n", arg1, arg2);
    redisReply *reply = redisCommand(context, "REPLCONF %s %s", arg1, arg2);

    /* Handle any error conditions */
    if (reply == NULL) {
        fprintf(stderr, "\nI/O error\n");
        exit(1);
    } else if (reply->type == REDIS_REPLY_ERROR) {
        /* non fatal, old versions may not support it */
        fprintf(stderr, "REPLCONF %s error: %s\n", arg1, reply->str);
        res = 0;
    }
    freeReplyObject(reply);
    return res;
}

void sendCapa(void) {
    sendReplconf("capa", "eof");
}

void sendRdbOnly(void) {
    sendReplconf("rdb-only", "1");
}

/* Read raw bytes through a redisContext. The read operation is not greedy
 * and may not fill the buffer entirely.
 */
static ssize_t readConn(redisContext *c, char *buf, size_t len) {
    return c->funcs->read(c, buf, len);
}

/* Sends SYNC and reads the number of bytes in the payload. Used both by
 * replicaMode() and getRDB().
 *
 * send_sync if 1 means we will explicitly send SYNC command. If 0 means
 * we will not send SYNC command, will send the command that in c->obuf.
 *
 * Returns the size of the RDB payload to read, or 0 in case an EOF marker is used and the size
 * is unknown, also returns 0 in case a PSYNC +CONTINUE was found (no RDB payload).
 *
 * The out_full_mode parameter if 1 means this is a full sync, if 0 means this is partial mode. */
unsigned long long sendSync(redisContext *c, int send_sync, char *out_eof, int *out_full_mode) {
    /* To start we need to send the SYNC command and return the payload.
     * The hiredis client lib does not understand this part of the protocol
     * and we don't want to mess with its buffers, so everything is performed
     * using direct low-level I/O. */
    char buf[4096], *p;
    ssize_t nread;

    if (out_full_mode) *out_full_mode = 1;

    if (send_sync) {
        /* Send the SYNC command. */
        if (cliWriteConn(c, "SYNC\r\n", 6) != 6) {
            fprintf(stderr, "Error writing to primary\n");
            exit(1);
        }
    } else {
        /* We have written the command into c->obuf before. */
        if (cliWriteConn(c, "", 0) != 0) {
            fprintf(stderr, "Error writing to primary\n");
            exit(1);
        }
    }

    /* Read $<payload>\r\n, making sure to read just up to "\n" */
    p = buf;
    while (1) {
        nread = readConn(c, p, 1);
        if (nread <= 0) {
            fprintf(stderr, "Error reading bulk length while SYNCing\n");
            exit(1);
        }
        if (*p == '\n' && p != buf) break;
        if (*p != '\n') p++;
        if (p >= buf + sizeof(buf) - 1) break; /* Go back one more char for null-term. */
    }
    *p = '\0';
    if (buf[0] == '-') {
        fprintf(stderr, "SYNC with primary failed: %s\n", buf);
        exit(1);
    }

    /* Handling PSYNC responses.
     * Read +FULLRESYNC <replid> <offset>\r\n, after that is the $<payload> or the $EOF:<40 bytes delimiter>
     * Read +CONTINUE <replid>\r\n or +CONTINUE\r\n, after that is the command stream */
    if (!strncmp(buf, "+FULLRESYNC", 11) || !strncmp(buf, "+CONTINUE", 9)) {
        int sync_partial = !strncmp(buf, "+CONTINUE", 9);
        fprintf(stderr, "PSYNC replied %s\n", buf);
        p = buf;
        while (1) {
            nread = readConn(c, p, 1);
            if (nread <= 0) {
                fprintf(stderr, "Error reading bulk length while PSYNCing\n");
                exit(1);
            }
            if (*p == '\n' && p != buf) break;
            if (*p != '\n') p++;
            if (p >= buf + sizeof(buf) - 1) break; /* Go back one more char for null-term. */
        }
        *p = '\0';

        if (sync_partial) {
            if (out_full_mode) *out_full_mode = 0;
            return 0;
        }
    }

    if (strncmp(buf + 1, "EOF:", 4) == 0 && strlen(buf + 5) >= RDB_EOF_MARK_SIZE) {
        memcpy(out_eof, buf + 5, RDB_EOF_MARK_SIZE);
        return 0;
    }
    return strtoull(buf + 1, NULL, 10);
}

static void replicaMode(int send_sync) {
    static char eofmark[RDB_EOF_MARK_SIZE];
    static char lastbytes[RDB_EOF_MARK_SIZE];
    static int usemark = 0;
    static int out_full_mode;
    unsigned long long payload = sendSync(context, send_sync, eofmark, &out_full_mode);
    char buf[1024];
    int original_output = config.output;
    char *info = out_full_mode ? "Full resync" : "Partial resync";

    if (out_full_mode == 1 && payload == 0) {
        /* SYNC with EOF marker or PSYNC +FULLRESYNC with EOF marker. */
        payload = ULLONG_MAX;
        memset(lastbytes, 0, RDB_EOF_MARK_SIZE);
        usemark = 1;
        fprintf(stderr,
                "%s with primary, discarding "
                "bytes of bulk transfer until EOF marker...\n",
                info);
    } else if (out_full_mode == 1 && payload != 0) {
        /* SYNC without EOF marker or PSYNC +FULLRESYNC. */
        fprintf(stderr,
                "%s with primary, discarding %llu "
                "bytes of bulk transfer...\n",
                info, payload);
    } else if (out_full_mode == 0 && payload == 0) {
        /* PSYNC +CONTINUE (no RDB payload). */
        fprintf(stderr, "%s with primary...\n", info);
    }

    /* Discard the payload. */
    while (payload) {
        ssize_t nread;

        nread = readConn(context, buf, (payload > sizeof(buf)) ? sizeof(buf) : payload);
        if (nread <= 0) {
            fprintf(stderr, "Error reading RDB payload while %sing\n", info);
            exit(1);
        }
        payload -= nread;

        if (usemark) {
            /* Update the last bytes array, and check if it matches our delimiter.*/
            if (nread >= RDB_EOF_MARK_SIZE) {
                memcpy(lastbytes, buf + nread - RDB_EOF_MARK_SIZE, RDB_EOF_MARK_SIZE);
            } else {
                int rem = RDB_EOF_MARK_SIZE - nread;
                memmove(lastbytes, lastbytes + nread, rem);
                memcpy(lastbytes + rem, buf, nread);
            }
            if (memcmp(lastbytes, eofmark, RDB_EOF_MARK_SIZE) == 0) break;
        }
    }

    if (usemark) {
        unsigned long long offset = ULLONG_MAX - payload;
        fprintf(stderr, "%s done after %llu bytes. Logging commands from primary.\n", info, offset);
        /* put the replica online */
        sleep(1);
        sendReplconf("ACK", "0");
    } else
        fprintf(stderr, "%s done. Logging commands from primary.\n", info);

    /* Now we can use hiredis to read the incoming protocol. */
    config.output = OUTPUT_CSV;
    while (cliReadReply(0) == REDIS_OK);
    config.output = original_output;
}

/*------------------------------------------------------------------------------
 * RDB transfer mode
 *--------------------------------------------------------------------------- */

/* This function implements --rdb, so it uses the replication protocol in order
 * to fetch the RDB file from a remote server. */
static void getRDB(clusterManagerNode *node) {
    int fd;
    redisContext *s;
    char *filename;
    if (node != NULL) {
        assert(node->context);
        s = node->context;
        filename = clusterManagerGetNodeRDBFilename(node);
    } else {
        s = context;
        filename = config.rdb_filename;
    }
    static char eofmark[RDB_EOF_MARK_SIZE];
    static char lastbytes[RDB_EOF_MARK_SIZE];
    static int usemark = 0;
    unsigned long long payload = sendSync(s, 1, eofmark, NULL);
    char buf[4096];

    if (payload == 0) {
        payload = ULLONG_MAX;
        memset(lastbytes, 0, RDB_EOF_MARK_SIZE);
        usemark = 1;
        fprintf(stderr,
                "SYNC sent to primary, writing bytes of bulk transfer "
                "until EOF marker to '%s'\n",
                filename);
    } else {
        fprintf(stderr, "SYNC sent to primary, writing %llu bytes to '%s'\n", payload, filename);
    }

    int write_to_stdout = !strcmp(filename, "-");
    /* Write to file. */
    if (write_to_stdout) {
        fd = STDOUT_FILENO;
    } else {
        fd = open(filename, O_CREAT | O_WRONLY, 0644);
        if (fd == -1) {
            fprintf(stderr, "Error opening '%s': %s\n", filename, strerror(errno));
            exit(1);
        }
    }

    while (payload) {
        ssize_t nread, nwritten;

        nread = readConn(s, buf, (payload > sizeof(buf)) ? sizeof(buf) : payload);
        if (nread <= 0) {
            fprintf(stderr, "I/O Error reading RDB payload from socket\n");
            exit(1);
        }
        nwritten = write(fd, buf, nread);
        if (nwritten != nread) {
            fprintf(stderr, "Error writing data to file: %s\n", (nwritten == -1) ? strerror(errno) : "short write");
            exit(1);
        }
        payload -= nread;

        if (usemark) {
            /* Update the last bytes array, and check if it matches our delimiter.*/
            if (nread >= RDB_EOF_MARK_SIZE) {
                memcpy(lastbytes, buf + nread - RDB_EOF_MARK_SIZE, RDB_EOF_MARK_SIZE);
            } else {
                int rem = RDB_EOF_MARK_SIZE - nread;
                memmove(lastbytes, lastbytes + nread, rem);
                memcpy(lastbytes + rem, buf, nread);
            }
            if (memcmp(lastbytes, eofmark, RDB_EOF_MARK_SIZE) == 0) break;
        }
    }
    if (usemark) {
        payload = ULLONG_MAX - payload - RDB_EOF_MARK_SIZE;
        if (!write_to_stdout && ftruncate(fd, payload) == -1)
            fprintf(stderr, "ftruncate failed: %s.\n", strerror(errno));
        fprintf(stderr, "Transfer finished with success after %llu bytes\n", payload);
    } else {
        fprintf(stderr, "Transfer finished with success.\n");
    }
    redisFree(s); /* Close the connection ASAP as fsync() may take time. */
    if (node) node->context = NULL;
    if (!write_to_stdout && fsync(fd) == -1) {
        fprintf(stderr, "Fail to fsync '%s': %s\n", filename, strerror(errno));
        exit(1);
    }
    close(fd);
    if (node) {
        sdsfree(filename);
        return;
    }
    exit(0);
}

/*------------------------------------------------------------------------------
 * Bulk import (pipe) mode
 *--------------------------------------------------------------------------- */

#define PIPEMODE_WRITE_LOOP_MAX_BYTES (128 * 1024)
static void pipeMode(void) {
    long long errors = 0, replies = 0, obuf_len = 0, obuf_pos = 0;
    char obuf[1024 * 16]; /* Output buffer */
    char aneterr[ANET_ERR_LEN];
    redisReply *reply;
    int eof = 0; /* True once we consumed all the standard input. */
    int done = 0;
    char magic[20]; /* Special reply we recognize. */
    time_t last_read_time = time(NULL);

    srand(time(NULL));

    /* Use non blocking I/O. */
    if (anetNonBlock(aneterr, context->fd) == ANET_ERR) {
        fprintf(stderr, "Can't set the socket in non blocking mode: %s\n", aneterr);
        exit(1);
    }

    context->flags &= ~REDIS_BLOCK;

    /* Transfer raw protocol and read replies from the server at the same
     * time. */
    while (!done) {
        int mask = AE_READABLE;

        if (!eof || obuf_len != 0) mask |= AE_WRITABLE;
        mask = aeWait(context->fd, mask, 1000);

        /* Handle the readable state: we can read replies from the server. */
        if (mask & AE_READABLE) {
            int read_error = 0;

            do {
                if (!read_error && redisBufferRead(context) == REDIS_ERR) {
                    read_error = 1;
                }

                reply = NULL;
                if (redisGetReply(context, (void **)&reply) == REDIS_ERR) {
                    fprintf(stderr, "Error reading replies from server\n");
                    exit(1);
                }
                if (reply) {
                    last_read_time = time(NULL);
                    if (reply->type == REDIS_REPLY_ERROR) {
                        fprintf(stderr, "%s\n", reply->str);
                        errors++;
                    } else if (eof && reply->type == REDIS_REPLY_STRING && reply->len == 20) {
                        /* Check if this is the reply to our final ECHO
                         * command. If so everything was received
                         * from the server. */
                        if (memcmp(reply->str, magic, 20) == 0) {
                            printf("Last reply received from server.\n");
                            done = 1;
                            replies--;
                        }
                    }
                    replies++;
                    freeReplyObject(reply);
                }
            } while (reply);

            /* Abort on read errors. We abort here because it is important
             * to consume replies even after a read error: this way we can
             * show a potential problem to the user. */
            if (read_error) exit(1);
        }

        /* Handle the writable state: we can send protocol to the server. */
        if (mask & AE_WRITABLE) {
            ssize_t loop_nwritten = 0;

            while (1) {
                /* Transfer current buffer to server. */
                if (obuf_len != 0) {
                    ssize_t nwritten = cliWriteConn(context, obuf + obuf_pos, obuf_len);

                    if (nwritten == -1) {
                        if (errno != EAGAIN && errno != EINTR) {
                            fprintf(stderr, "Error writing to the server: %s\n", strerror(errno));
                            exit(1);
                        } else {
                            nwritten = 0;
                        }
                    }
                    obuf_len -= nwritten;
                    obuf_pos += nwritten;
                    loop_nwritten += nwritten;
                    if (obuf_len != 0) break; /* Can't accept more data. */
                }
                if (context->err) {
                    fprintf(stderr, "Server I/O Error: %s\n", context->errstr);
                    exit(1);
                }
                /* If buffer is empty, load from stdin. */
                if (obuf_len == 0 && !eof) {
                    ssize_t nread = read(STDIN_FILENO, obuf, sizeof(obuf));

                    if (nread == 0) {
                        /* The ECHO sequence starts with a "\r\n" so that if there
                         * is garbage in the protocol we read from stdin, the ECHO
                         * will likely still be properly formatted.
                         * CRLF is ignored by the server, so it has no effects. */
                        char echo[] = "\r\n*2\r\n$4\r\nECHO\r\n$20\r\n01234567890123456789\r\n";
                        int j;

                        eof = 1;
                        /* Everything transferred, so we queue a special
                         * ECHO command that we can match in the replies
                         * to make sure everything was read from the server. */
                        for (j = 0; j < 20; j++) magic[j] = rand() & 0xff;
                        memcpy(echo + 21, magic, 20);
                        memcpy(obuf, echo, sizeof(echo) - 1);
                        obuf_len = sizeof(echo) - 1;
                        obuf_pos = 0;
                        printf("All data transferred. Waiting for the last reply...\n");
                    } else if (nread == -1) {
                        fprintf(stderr, "Error reading from stdin: %s\n", strerror(errno));
                        exit(1);
                    } else {
                        obuf_len = nread;
                        obuf_pos = 0;
                    }
                }
                if ((obuf_len == 0 && eof) || loop_nwritten > PIPEMODE_WRITE_LOOP_MAX_BYTES) break;
            }
        }

        /* Handle timeout, that is, we reached EOF, and we are not getting
         * replies from the server for a few seconds, nor the final ECHO is
         * received. */
        if (eof && config.pipe_timeout > 0 && time(NULL) - last_read_time > config.pipe_timeout) {
            fprintf(stderr, "No replies for %d seconds: exiting.\n", config.pipe_timeout);
            errors++;
            break;
        }
    }
    printf("errors: %lld, replies: %lld\n", errors, replies);
    if (errors)
        exit(1);
    else
        exit(0);
}

/*------------------------------------------------------------------------------
 * Find big keys
 *--------------------------------------------------------------------------- */

static redisReply *sendScan(unsigned long long *it) {
    redisReply *reply;

    if (config.pattern)
        reply = redisCommand(context, "SCAN %llu MATCH %b COUNT %d", *it, config.pattern, sdslen(config.pattern),
                             config.count);
    else
        reply = redisCommand(context, "SCAN %llu COUNT %d", *it, config.count);

    /* Handle any error conditions */
    if (reply == NULL) {
        fprintf(stderr, "\nI/O error\n");
        exit(1);
    } else if (reply->type == REDIS_REPLY_ERROR) {
        fprintf(stderr, "SCAN error: %s\n", reply->str);
        exit(1);
    } else if (reply->type != REDIS_REPLY_ARRAY) {
        fprintf(stderr, "Non ARRAY response from SCAN!\n");
        exit(1);
    } else if (reply->elements != 2) {
        fprintf(stderr, "Invalid element count from SCAN!\n");
        exit(1);
    }

    /* Validate our types are correct */
    assert(reply->element[0]->type == REDIS_REPLY_STRING);
    assert(reply->element[1]->type == REDIS_REPLY_ARRAY);

    /* Update iterator */
    *it = strtoull(reply->element[0]->str, NULL, 10);

    return reply;
}

static int getDbSize(void) {
    redisReply *reply;
    int size;

    reply = redisCommand(context, "DBSIZE");

    if (reply == NULL) {
        fprintf(stderr, "\nI/O error\n");
        exit(1);
    } else if (reply->type == REDIS_REPLY_ERROR) {
        fprintf(stderr, "Couldn't determine DBSIZE: %s\n", reply->str);
        exit(1);
    } else if (reply->type != REDIS_REPLY_INTEGER) {
        fprintf(stderr, "Non INTEGER response from DBSIZE!\n");
        exit(1);
    }

    /* Grab the number of keys and free our reply */
    size = reply->integer;
    freeReplyObject(reply);

    return size;
}

static int getDatabases(void) {
    redisReply *reply;
    int dbnum;

    reply = redisCommand(context, "CONFIG GET databases");

    if (reply == NULL) {
        fprintf(stderr, "\nI/O error\n");
        exit(1);
    } else if (reply->type == REDIS_REPLY_ERROR) {
        dbnum = 16;
        fprintf(stderr, "CONFIG GET databases fails: %s, use default value 16 instead\n", reply->str);
    } else {
        assert(reply->type == (config.current_resp3 ? REDIS_REPLY_MAP : REDIS_REPLY_ARRAY));
        assert(reply->elements == 2);
        dbnum = atoi(reply->element[1]->str);
    }

    freeReplyObject(reply);
    return dbnum;
}

typedef struct {
    char *name;
    char *sizecmd;
    char *sizeunit;
    unsigned long long biggest;
    unsigned long long count;
    unsigned long long totalsize;
    sds biggest_key;
} typeinfo;

typeinfo type_string = {"string", "STRLEN", "bytes"};
typeinfo type_list = {"list", "LLEN", "items"};
typeinfo type_set = {"set", "SCARD", "members"};
typeinfo type_hash = {"hash", "HLEN", "fields"};
typeinfo type_zset = {"zset", "ZCARD", "members"};
typeinfo type_stream = {"stream", "XLEN", "entries"};
typeinfo type_other = {"other", NULL, "?"};

static typeinfo *typeinfo_add(dict *types, char *name, typeinfo *type_template) {
    typeinfo *info = zmalloc(sizeof(typeinfo));
    *info = *type_template;
    info->name = sdsnew(name);
    dictAdd(types, info->name, info);
    return info;
}

void type_free(dict *d, void *val) {
    typeinfo *info = val;
    UNUSED(d);
    if (info->biggest_key) sdsfree(info->biggest_key);
    sdsfree(info->name);
    zfree(info);
}

static dictType typeinfoDictType = {
    dictSdsHash,       /* hash function */
    NULL,              /* key dup */
    dictSdsKeyCompare, /* key compare */
    NULL,              /* key destructor (owned by the value)*/
    type_free,         /* val destructor */
    NULL               /* allow to expand */
};

static void getKeyTypes(dict *types_dict, redisReply *keys, typeinfo **types) {
    redisReply *reply;
    unsigned int i;

    /* Pipeline TYPE commands */
    for (i = 0; i < keys->elements; i++) {
        const char *argv[] = {"TYPE", keys->element[i]->str};
        size_t lens[] = {4, keys->element[i]->len};
        redisAppendCommandArgv(context, 2, argv, lens);
    }

    /* Retrieve types */
    for (i = 0; i < keys->elements; i++) {
        if (redisGetReply(context, (void **)&reply) != REDIS_OK) {
            fprintf(stderr, "Error getting type for key '%s' (%d: %s)\n", keys->element[i]->str, context->err,
                    context->errstr);
            exit(1);
        } else if (reply->type != REDIS_REPLY_STATUS) {
            if (reply->type == REDIS_REPLY_ERROR) {
                fprintf(stderr, "TYPE returned an error: %s\n", reply->str);
            } else {
                fprintf(stderr, "Invalid reply type (%d) for TYPE on key '%s'!\n", reply->type, keys->element[i]->str);
            }
            exit(1);
        }

        sds typereply = sdsnew(reply->str);
        dictEntry *de = dictFind(types_dict, typereply);
        sdsfree(typereply);
        typeinfo *type = NULL;
        if (de)
            type = dictGetVal(de);
        else if (strcmp(reply->str, "none")) /* create new types for modules, (but not for deleted keys) */
            type = typeinfo_add(types_dict, reply->str, &type_other);
        types[i] = type;
        freeReplyObject(reply);
    }
}

static void
getKeySizes(redisReply *keys, typeinfo **types, unsigned long long *sizes, int memkeys, unsigned memkeys_samples) {
    redisReply *reply;
    unsigned int i;

    /* Pipeline size commands */
    for (i = 0; i < keys->elements; i++) {
        /* Skip keys that disappeared between SCAN and TYPE (or unknown types when not in memkeys mode) */
        if (!types[i] || (!types[i]->sizecmd && !memkeys)) continue;

        if (!memkeys) {
            const char *argv[] = {types[i]->sizecmd, keys->element[i]->str};
            size_t lens[] = {strlen(types[i]->sizecmd), keys->element[i]->len};
            redisAppendCommandArgv(context, 2, argv, lens);
        } else if (memkeys_samples == 0) {
            const char *argv[] = {"MEMORY", "USAGE", keys->element[i]->str};
            size_t lens[] = {6, 5, keys->element[i]->len};
            redisAppendCommandArgv(context, 3, argv, lens);
        } else {
            sds samplesstr = sdsfromlonglong(memkeys_samples);
            const char *argv[] = {"MEMORY", "USAGE", keys->element[i]->str, "SAMPLES", samplesstr};
            size_t lens[] = {6, 5, keys->element[i]->len, 7, sdslen(samplesstr)};
            redisAppendCommandArgv(context, 5, argv, lens);
            sdsfree(samplesstr);
        }
    }

    /* Retrieve sizes */
    for (i = 0; i < keys->elements; i++) {
        /* Skip keys that disappeared between SCAN and TYPE (or unknown types when not in memkeys mode) */
        if (!types[i] || (!types[i]->sizecmd && !memkeys)) {
            sizes[i] = 0;
            continue;
        }

        /* Retrieve size */
        if (redisGetReply(context, (void **)&reply) != REDIS_OK) {
            fprintf(stderr, "Error getting size for key '%s' (%d: %s)\n", keys->element[i]->str, context->err,
                    context->errstr);
            exit(1);
        } else if (reply->type != REDIS_REPLY_INTEGER) {
            /* Theoretically the key could have been removed and
             * added as a different type between TYPE and SIZE */
            fprintf(stderr, "Warning:  %s on '%s' failed (may have changed type)\n",
                    !memkeys ? types[i]->sizecmd : "MEMORY USAGE", keys->element[i]->str);
            sizes[i] = 0;
        } else {
            sizes[i] = reply->integer;
        }

        freeReplyObject(reply);
    }
}

static void longStatLoopModeStop(int s) {
    UNUSED(s);
    force_cancel_loop = 1;
}

/* In cluster mode we may need to send the READONLY command.
   Ignore the error in case the server isn't using cluster mode. */
static void sendReadOnly(void) {
    redisReply *read_reply;
    read_reply = redisCommand(context, "READONLY");
    if (read_reply == NULL) {
        fprintf(stderr, "\nI/O error\n");
        exit(1);
    } else if (read_reply->type == REDIS_REPLY_ERROR &&
               strcmp(read_reply->str, "ERR This instance has cluster support disabled") != 0) {
        fprintf(stderr, "Error: %s\n", read_reply->str);
        exit(1);
    }
    freeReplyObject(read_reply);
}

static void findBigKeys(int memkeys, unsigned memkeys_samples) {
    unsigned long long sampled = 0, total_keys, totlen = 0, *sizes = NULL, it = 0, scan_loops = 0;
    redisReply *reply, *keys;
    unsigned int arrsize = 0, i;
    dictIterator *di;
    dictEntry *de;
    typeinfo **types = NULL;
    double pct;

    dict *types_dict = dictCreate(&typeinfoDictType);
    typeinfo_add(types_dict, "string", &type_string);
    typeinfo_add(types_dict, "list", &type_list);
    typeinfo_add(types_dict, "set", &type_set);
    typeinfo_add(types_dict, "hash", &type_hash);
    typeinfo_add(types_dict, "zset", &type_zset);
    typeinfo_add(types_dict, "stream", &type_stream);

    signal(SIGINT, longStatLoopModeStop);
    /* Total keys pre scanning */
    total_keys = getDbSize();

    /* Status message */
    printf("\n# Scanning the entire keyspace to find biggest keys as well as\n");
    printf("# average sizes per key type.  You can use -i 0.1 to sleep 0.1 sec\n");
    printf("# per 100 SCAN commands (not usually needed).\n\n");

    /* Use readonly in cluster */
    sendReadOnly();

    /* SCAN loop */
    do {
        /* Calculate approximate percentage completion */
        pct = 100 * (double)sampled / total_keys;

        /* Grab some keys and point to the keys array */
        reply = sendScan(&it);
        scan_loops++;
        keys = reply->element[1];

        /* Reallocate our type and size array if we need to */
        if (keys->elements > arrsize) {
            types = zrealloc(types, sizeof(typeinfo *) * keys->elements);
            sizes = zrealloc(sizes, sizeof(unsigned long long) * keys->elements);

            if (!types || !sizes) {
                fprintf(stderr, "Failed to allocate storage for keys!\n");
                exit(1);
            }

            arrsize = keys->elements;
        }

        /* Retrieve types and then sizes */
        getKeyTypes(types_dict, keys, types);
        getKeySizes(keys, types, sizes, memkeys, memkeys_samples);

        /* Now update our stats */
        for (i = 0; i < keys->elements; i++) {
            typeinfo *type = types[i];
            /* Skip keys that disappeared between SCAN and TYPE */
            if (!type) continue;

            type->totalsize += sizes[i];
            type->count++;
            totlen += keys->element[i]->len;
            sampled++;

            if (type->biggest < sizes[i]) {
                /* Keep track of biggest key name for this type */
                if (type->biggest_key) sdsfree(type->biggest_key);
                type->biggest_key = sdscatrepr(sdsempty(), keys->element[i]->str, keys->element[i]->len);
                if (!type->biggest_key) {
                    fprintf(stderr, "Failed to allocate memory for key!\n");
                    exit(1);
                }

                printf("[%05.2f%%] Biggest %-6s found so far '%s' with %llu %s\n", pct, type->name, type->biggest_key,
                       sizes[i], !memkeys ? type->sizeunit : "bytes");

                /* Keep track of the biggest size for this type */
                type->biggest = sizes[i];
            }

            /* Update overall progress */
            if (sampled % 1000000 == 0) {
                printf("[%05.2f%%] Sampled %llu keys so far\n", pct, sampled);
            }
        }

        /* Sleep if we've been directed to do so */
        if (config.interval && (scan_loops % 100) == 0) {
            usleep(config.interval);
        }

        freeReplyObject(reply);
    } while (force_cancel_loop == 0 && it != 0);

    if (types) zfree(types);
    if (sizes) zfree(sizes);

    /* We're done */
    printf("\n-------- summary -------\n\n");
    if (force_cancel_loop) printf("[%05.2f%%] ", pct);
    printf("Sampled %llu keys in the keyspace!\n", sampled);
    printf("Total key length in bytes is %llu (avg len %.2f)\n\n", totlen, totlen ? (double)totlen / sampled : 0);

    /* Output the biggest keys we found, for types we did find */
    di = dictGetIterator(types_dict);
    while ((de = dictNext(di))) {
        typeinfo *type = dictGetVal(de);
        if (type->biggest_key) {
            printf("Biggest %6s found '%s' has %llu %s\n", type->name, type->biggest_key, type->biggest,
                   !memkeys ? type->sizeunit : "bytes");
        }
    }
    dictReleaseIterator(di);

    printf("\n");

    di = dictGetIterator(types_dict);
    while ((de = dictNext(di))) {
        typeinfo *type = dictGetVal(de);
        printf("%llu %ss with %llu %s (%05.2f%% of keys, avg size %.2f)\n", type->count, type->name, type->totalsize,
               !memkeys ? type->sizeunit : "bytes", sampled ? 100 * (double)type->count / sampled : 0,
               type->count ? (double)type->totalsize / type->count : 0);
    }
    dictReleaseIterator(di);

    dictRelease(types_dict);

    /* Success! */
    exit(0);
}

static void getKeyFreqs(redisReply *keys, unsigned long long *freqs) {
    redisReply *reply;
    unsigned int i;

    /* Pipeline OBJECT freq commands */
    for (i = 0; i < keys->elements; i++) {
        const char *argv[] = {"OBJECT", "FREQ", keys->element[i]->str};
        size_t lens[] = {6, 4, keys->element[i]->len};
        redisAppendCommandArgv(context, 3, argv, lens);
    }

    /* Retrieve freqs */
    for (i = 0; i < keys->elements; i++) {
        if (redisGetReply(context, (void **)&reply) != REDIS_OK) {
            sds keyname = sdscatrepr(sdsempty(), keys->element[i]->str, keys->element[i]->len);
            fprintf(stderr, "Error getting freq for key '%s' (%d: %s)\n", keyname, context->err, context->errstr);
            sdsfree(keyname);
            exit(1);
        } else if (reply->type != REDIS_REPLY_INTEGER) {
            if (reply->type == REDIS_REPLY_ERROR) {
                fprintf(stderr, "Error: %s\n", reply->str);
                exit(1);
            } else {
                sds keyname = sdscatrepr(sdsempty(), keys->element[i]->str, keys->element[i]->len);
                fprintf(stderr, "Warning: OBJECT freq on '%s' failed (may have been deleted)\n", keyname);
                sdsfree(keyname);
                freqs[i] = 0;
            }
        } else {
            freqs[i] = reply->integer;
        }
        freeReplyObject(reply);
    }
}

#define HOTKEYS_SAMPLE 16
static void findHotKeys(void) {
    redisReply *keys, *reply;
    unsigned long long counters[HOTKEYS_SAMPLE] = {0};
    sds hotkeys[HOTKEYS_SAMPLE] = {NULL};
    unsigned long long sampled = 0, total_keys, *freqs = NULL, it = 0, scan_loops = 0;
    unsigned int arrsize = 0, i, k;
    double pct;

    signal(SIGINT, longStatLoopModeStop);
    /* Total keys pre scanning */
    total_keys = getDbSize();

    /* Status message */
    printf("\n# Scanning the entire keyspace to find hot keys as well as\n");
    printf("# average sizes per key type.  You can use -i 0.1 to sleep 0.1 sec\n");
    printf("# per 100 SCAN commands (not usually needed).\n\n");

    /* Use readonly in cluster */
    sendReadOnly();

    /* SCAN loop */
    do {
        /* Calculate approximate percentage completion */
        pct = 100 * (double)sampled / total_keys;

        /* Grab some keys and point to the keys array */
        reply = sendScan(&it);
        scan_loops++;
        keys = reply->element[1];

        /* Reallocate our freqs array if we need to */
        if (keys->elements > arrsize) {
            freqs = zrealloc(freqs, sizeof(unsigned long long) * keys->elements);

            if (!freqs) {
                fprintf(stderr, "Failed to allocate storage for keys!\n");
                exit(1);
            }

            arrsize = keys->elements;
        }

        getKeyFreqs(keys, freqs);

        /* Now update our stats */
        for (i = 0; i < keys->elements; i++) {
            sampled++;
            /* Update overall progress */
            if (sampled % 1000000 == 0) {
                printf("[%05.2f%%] Sampled %llu keys so far\n", pct, sampled);
            }

            /* Use eviction pool here */
            k = 0;
            while (k < HOTKEYS_SAMPLE && freqs[i] > counters[k]) k++;
            if (k == 0) continue;
            k--;
            if (k == 0 || counters[k] == 0) {
                sdsfree(hotkeys[k]);
            } else {
                sdsfree(hotkeys[0]);
                memmove(counters, counters + 1, sizeof(counters[0]) * k);
                memmove(hotkeys, hotkeys + 1, sizeof(hotkeys[0]) * k);
            }
            counters[k] = freqs[i];
            hotkeys[k] = sdscatrepr(sdsempty(), keys->element[i]->str, keys->element[i]->len);
            printf("[%05.2f%%] Hot key '%s' found so far with counter %llu\n", pct, hotkeys[k], freqs[i]);
        }

        /* Sleep if we've been directed to do so */
        if (config.interval && (scan_loops % 100) == 0) {
            usleep(config.interval);
        }

        freeReplyObject(reply);
    } while (force_cancel_loop == 0 && it != 0);

    if (freqs) zfree(freqs);

    /* We're done */
    printf("\n-------- summary -------\n\n");
    if (force_cancel_loop) printf("[%05.2f%%] ", pct);
    printf("Sampled %llu keys in the keyspace!\n", sampled);

    for (i = 1; i <= HOTKEYS_SAMPLE; i++) {
        k = HOTKEYS_SAMPLE - i;
        if (counters[k] > 0) {
            printf("hot key found with counter: %llu\tkeyname: %s\n", counters[k], hotkeys[k]);
            sdsfree(hotkeys[k]);
        }
    }

    exit(0);
}

/*------------------------------------------------------------------------------
 * Stats mode
 *--------------------------------------------------------------------------- */

/* Return the specified INFO field from the INFO command output "info".
 * A new buffer is allocated for the result, that needs to be free'd.
 * If the field is not found NULL is returned. */
static char *getInfoField(char *info, char *field) {
    char *p = strstr(info, field);
    char *n1, *n2;
    char *result;

    if (!p) return NULL;
    p += strlen(field) + 1;
    n1 = strchr(p, '\r');
    n2 = strchr(p, ',');
    if (n2 && n2 < n1) n1 = n2;
    result = zmalloc(sizeof(char) * (n1 - p) + 1);
    memcpy(result, p, (n1 - p));
    result[n1 - p] = '\0';
    return result;
}

/* Like the above function but automatically convert the result into
 * a long. On error (missing field) LONG_MIN is returned. */
static long getLongInfoField(char *info, char *field) {
    char *value = getInfoField(info, field);
    long l;

    if (!value) return LONG_MIN;
    l = strtol(value, NULL, 10);
    zfree(value);
    return l;
}

/* Convert number of bytes into a human readable string of the form:
 * 100B, 2G, 100M, 4K, and so forth. */
void bytesToHuman(char *s, size_t size, long long n) {
    double d;

    if (n < 0) {
        *s = '-';
        s++;
        n = -n;
    }
    if (n < 1024) {
        /* Bytes */
        snprintf(s, size, "%lldB", n);
        return;
    } else if (n < (1024 * 1024)) {
        d = (double)n / (1024);
        snprintf(s, size, "%.2fK", d);
    } else if (n < (1024LL * 1024 * 1024)) {
        d = (double)n / (1024 * 1024);
        snprintf(s, size, "%.2fM", d);
    } else if (n < (1024LL * 1024 * 1024 * 1024)) {
        d = (double)n / (1024LL * 1024 * 1024);
        snprintf(s, size, "%.2fG", d);
    }
}

static void statMode(void) {
    redisReply *reply;
    long aux, requests = 0;
    int dbnum = getDatabases();
    int i = 0;

    while (1) {
        char buf[64];
        int j;

        reply = reconnectingRedisCommand(context, "INFO");
        if (reply == NULL) {
            fprintf(stderr, "\nI/O error\n");
            exit(1);
        } else if (reply->type == REDIS_REPLY_ERROR) {
            fprintf(stderr, "ERROR: %s\n", reply->str);
            exit(1);
        }

        if ((i++ % 20) == 0) {
            printf("------- data ------ --------------------- load -------------------- - child -\n"
                   "keys       mem      clients blocked requests            connections          \n");
        }

        /* Keys */
        aux = 0;
        for (j = 0; j < dbnum; j++) {
            long k;

            snprintf(buf, sizeof(buf), "db%d:keys", j);
            k = getLongInfoField(reply->str, buf);
            if (k == LONG_MIN) continue;
            aux += k;
        }
        snprintf(buf, sizeof(buf), "%ld", aux);
        printf("%-11s", buf);

        /* Used memory */
        aux = getLongInfoField(reply->str, "used_memory");
        bytesToHuman(buf, sizeof(buf), aux);
        printf("%-8s", buf);

        /* Clients */
        aux = getLongInfoField(reply->str, "connected_clients");
        snprintf(buf, sizeof(buf), "%ld", aux);
        printf(" %-8s", buf);

        /* Blocked (BLPOPPING) Clients */
        aux = getLongInfoField(reply->str, "blocked_clients");
        snprintf(buf, sizeof(buf), "%ld", aux);
        printf("%-8s", buf);

        /* Requests */
        aux = getLongInfoField(reply->str, "total_commands_processed");
        snprintf(buf, sizeof(buf), "%ld (+%ld)", aux, requests == 0 ? 0 : aux - requests);
        printf("%-19s", buf);
        requests = aux;

        /* Connections */
        aux = getLongInfoField(reply->str, "total_connections_received");
        snprintf(buf, sizeof(buf), "%ld", aux);
        printf(" %-12s", buf);

        /* Children */
        aux = getLongInfoField(reply->str, "bgsave_in_progress");
        aux |= getLongInfoField(reply->str, "aof_rewrite_in_progress") << 1;
        aux |= getLongInfoField(reply->str, "loading") << 2;
        switch (aux) {
        case 0: break;
        case 1: printf("SAVE"); break;
        case 2: printf("AOF"); break;
        case 3: printf("SAVE+AOF"); break;
        case 4: printf("LOAD"); break;
        }

        printf("\n");
        freeReplyObject(reply);
        usleep(config.interval);
    }
}

/*------------------------------------------------------------------------------
 * Scan mode
 *--------------------------------------------------------------------------- */

static void scanMode(void) {
    redisReply *reply;
    unsigned long long cur = 0;
    signal(SIGINT, longStatLoopModeStop);
    do {
        reply = sendScan(&cur);
        for (unsigned int j = 0; j < reply->element[1]->elements; j++) {
            if (config.output == OUTPUT_STANDARD) {
                sds out =
                    sdscatrepr(sdsempty(), reply->element[1]->element[j]->str, reply->element[1]->element[j]->len);
                printf("%s\n", out);
                sdsfree(out);
            } else {
                printf("%s\n", reply->element[1]->element[j]->str);
            }
        }
        freeReplyObject(reply);
        if (config.interval) usleep(config.interval);
    } while (force_cancel_loop == 0 && cur != 0);

    exit(0);
}

/*------------------------------------------------------------------------------
 * LRU test mode
 *--------------------------------------------------------------------------- */

/* Return an integer from min to max (both inclusive) using a power-law
 * distribution, depending on the value of alpha: the greater the alpha
 * the more bias towards lower values.
 *
 * With alpha = 6.2 the output follows the 80-20 rule where 20% of
 * the returned numbers will account for 80% of the frequency. */
long long powerLawRand(long long min, long long max, double alpha) {
    double pl, r;

    max += 1;
    r = ((double)rand()) / RAND_MAX;
    pl = pow(((pow(max, alpha + 1) - pow(min, alpha + 1)) * r + pow(min, alpha + 1)), (1.0 / (alpha + 1)));
    return (max - 1 - (long long)pl) + min;
}

/* Generates a key name among a set of lru_test_sample_size keys, using
 * an 80-20 distribution. */
void LRUTestGenKey(char *buf, size_t buflen) {
    snprintf(buf, buflen, "lru:%lld", powerLawRand(1, config.lru_test_sample_size, 6.2));
}

#define LRU_CYCLE_PERIOD 1000 /* 1000 milliseconds. */
#define LRU_CYCLE_PIPELINE_SIZE 250
static void LRUTestMode(void) {
    redisReply *reply;
    char key[128];
    long long start_cycle;
    int j;

    srand(time(NULL) ^ getpid());
    while (1) {
        /* Perform cycles of 1 second with 50% writes and 50% reads.
         * We use pipelining batching writes / reads N times per cycle in order
         * to fill the target instance easily. */
        start_cycle = mstime();
        long long hits = 0, misses = 0;
        while (mstime() - start_cycle < LRU_CYCLE_PERIOD) {
            /* Write cycle. */
            for (j = 0; j < LRU_CYCLE_PIPELINE_SIZE; j++) {
                char val[6];
                val[5] = '\0';
                for (int i = 0; i < 5; i++) val[i] = 'A' + rand() % ('z' - 'A');
                LRUTestGenKey(key, sizeof(key));
                redisAppendCommand(context, "SET %s %s", key, val);
            }
            for (j = 0; j < LRU_CYCLE_PIPELINE_SIZE; j++) redisGetReply(context, (void **)&reply);

            /* Read cycle. */
            for (j = 0; j < LRU_CYCLE_PIPELINE_SIZE; j++) {
                LRUTestGenKey(key, sizeof(key));
                redisAppendCommand(context, "GET %s", key);
            }
            for (j = 0; j < LRU_CYCLE_PIPELINE_SIZE; j++) {
                if (redisGetReply(context, (void **)&reply) == REDIS_OK) {
                    switch (reply->type) {
                    case REDIS_REPLY_ERROR: fprintf(stderr, "%s\n", reply->str); break;
                    case REDIS_REPLY_NIL: misses++; break;
                    default: hits++; break;
                    }
                }
            }

            if (context->err) {
                fprintf(stderr, "I/O error during LRU test\n");
                exit(1);
            }
        }
        /* Print stats. */
        printf("%lld Gets/sec | Hits: %lld (%.2f%%) | Misses: %lld (%.2f%%)\n", hits + misses, hits,
               (double)hits / (hits + misses) * 100, misses, (double)misses / (hits + misses) * 100);
    }
    exit(0);
}

/*------------------------------------------------------------------------------
 * Intrinsic latency mode.
 *
 * Measure max latency of a running process that does not result from
 * syscalls. Basically this software should provide a hint about how much
 * time the kernel leaves the process without a chance to run.
 *--------------------------------------------------------------------------- */

/* This is just some computation the compiler can't optimize out.
 * Should run in less than 100-200 microseconds even using very
 * slow hardware. Runs in less than 10 microseconds in modern HW. */
unsigned long compute_something_fast(void) {
    unsigned char s[256], i, j, t;
    int count = 1000, k;
    unsigned long output = 0;

    for (k = 0; k < 256; k++) s[k] = k;

    i = 0;
    j = 0;
    while (count--) {
        i++;
        j = j + s[i];
        t = s[i];
        s[i] = s[j];
        s[j] = t;
        output += s[(s[i] + s[j]) & 255];
    }
    return output;
}

static void sigIntHandler(int s) {
    UNUSED(s);

    if (config.monitor_mode || config.pubsub_mode) {
        close(context->fd);
        context->fd = REDIS_INVALID_FD;
        config.blocking_state_aborted = 1;
    } else {
        exit(1);
    }
}

static void intrinsicLatencyMode(void) {
    long long test_end, run_time, max_latency = 0, runs = 0;

    run_time = (long long)config.intrinsic_latency_duration * 1000000;
    test_end = ustime() + run_time;
    signal(SIGINT, longStatLoopModeStop);

    while (1) {
        long long start, end, latency;

        start = ustime();
        compute_something_fast();
        end = ustime();
        latency = end - start;
        runs++;
        if (latency <= 0) continue;

        /* Reporting */
        if (latency > max_latency) {
            max_latency = latency;
            printf("Max latency so far: %lld microseconds.\n", max_latency);
        }

        double avg_us = (double)run_time / runs;
        double avg_ns = avg_us * 1e3;
        if (force_cancel_loop || end > test_end) {
            printf("\n%lld total runs "
                   "(avg latency: "
                   "%.4f microseconds / %.2f nanoseconds per run).\n",
                   runs, avg_us, avg_ns);
            printf("Worst run took %.0fx longer than the average latency.\n", max_latency / avg_us);
            exit(0);
        }
    }
}

static sds askPassword(const char *msg) {
    linenoiseMaskModeEnable();
    sds auth = linenoise(msg);
    linenoiseMaskModeDisable();
    return auth;
}

/* Prints out the hint completion string for a given input prefix string. */
void testHint(const char *input) {
    cliInitHelp();

    sds hint = getHintForInput(input);
    printf("%s\n", hint);
    exit(0);
}

sds readHintSuiteLine(char buf[], size_t size, FILE *fp) {
    while (fgets(buf, size, fp) != NULL) {
        if (buf[0] != '#') {
            sds input = sdsnew(buf);

            /* Strip newline. */
            input = sdstrim(input, "\n");
            return input;
        }
    }
    return NULL;
}

/* Runs a suite of hint completion tests contained in a file. */
void testHintSuite(char *filename) {
    FILE *fp;
    char buf[256];
    sds line, input, expected, hint;
    int pass = 0, fail = 0;
    int argc;
    char **argv;

    fp = fopen(filename, "r");
    if (!fp) {
        fprintf(stderr, "Can't open file '%s': %s\n", filename, strerror(errno));
        exit(-1);
    }

    cliInitHelp();

    while (1) {
        line = readHintSuiteLine(buf, sizeof(buf), fp);
        if (line == NULL) break;
        argv = sdssplitargs(line, &argc);
        sdsfree(line);
        if (argc == 0) {
            sdsfreesplitres(argv, argc);
            continue;
        }

        if (argc == 1) {
            fprintf(stderr, "Missing expected hint for input '%s'\n", argv[0]);
            exit(-1);
        }
        input = argv[0];
        expected = argv[1];
        hint = getHintForInput(input);
        if (config.verbose) {
            printf("Input: '%s', Expected: '%s', Hint: '%s'\n", input, expected, hint);
        }

        /* Strip trailing spaces from hint - they don't matter. */
        while (hint != NULL && sdslen(hint) > 0 && hint[sdslen(hint) - 1] == ' ') {
            sdssetlen(hint, sdslen(hint) - 1);
            hint[sdslen(hint)] = '\0';
        }

        if (hint == NULL || strcmp(hint, expected) != 0) {
            fprintf(stderr, "Test case '%s' FAILED: expected '%s', got '%s'\n", input, expected, hint);
            ++fail;
        } else {
            ++pass;
        }
        sdsfreesplitres(argv, argc);
        sdsfree(hint);
    }
    fclose(fp);

    printf("%s: %d/%d passed\n", fail == 0 ? "SUCCESS" : "FAILURE", pass, pass + fail);
    exit(fail);
}

/*------------------------------------------------------------------------------
 * Program main()
 *--------------------------------------------------------------------------- */

int main(int argc, char **argv) {
    int firstarg;
    struct timeval tv;

    memset(&config.sslconfig, 0, sizeof(config.sslconfig));
    config.conn_info.hostip = sdsnew("127.0.0.1");
    config.conn_info.hostport = 6379;
    config.connect_timeout.tv_sec = 0;
    config.connect_timeout.tv_usec = 0;
    config.hostsocket = NULL;
    config.repeat = 1;
    config.interval = 0;
    config.dbnum = 0;
    config.conn_info.input_dbnum = 0;
    config.interactive = 0;
    config.shutdown = 0;
    config.monitor_mode = 0;
    config.pubsub_mode = 0;
    config.blocking_state_aborted = 0;
    config.latency_mode = 0;
    config.latency_dist_mode = 0;
    config.latency_history = 0;
    config.lru_test_mode = 0;
    config.lru_test_sample_size = 0;
    config.cluster_mode = 0;
    config.cluster_send_asking = 0;
    config.replica_mode = 0;
    config.getrdb_mode = 0;
    config.get_functions_rdb_mode = 0;
    config.stat_mode = 0;
    config.scan_mode = 0;
    config.count = 10;
    config.intrinsic_latency_mode = 0;
    config.pattern = NULL;
    config.rdb_filename = NULL;
    config.pipe_mode = 0;
    config.pipe_timeout = CLI_DEFAULT_PIPE_TIMEOUT;
    config.bigkeys = 0;
    config.memkeys = 0;
    config.hotkeys = 0;
    config.stdin_lastarg = 0;
    config.stdin_tag_arg = 0;
    config.stdin_tag_name = NULL;
    config.conn_info.auth = NULL;
    config.askpass = 0;
    config.conn_info.user = NULL;
    config.eval = NULL;
    config.eval_ldb = 0;
    config.eval_ldb_end = 0;
    config.eval_ldb_sync = 0;
    config.enable_ldb_on_eval = 0;
    config.last_cmd_type = -1;
    config.last_reply = NULL;
    config.verbose = 0;
    config.set_errcode = 0;
    config.no_auth_warning = 0;
    config.in_multi = 0;
    config.server_version = NULL;
    config.prefer_ipv4 = 0;
    config.prefer_ipv6 = 0;
    config.cluster_manager_command.name = NULL;
    config.cluster_manager_command.argc = 0;
    config.cluster_manager_command.argv = NULL;
    config.cluster_manager_command.stdin_arg = NULL;
    config.cluster_manager_command.flags = 0;
    config.cluster_manager_command.replicas = 0;
    config.cluster_manager_command.from = NULL;
    config.cluster_manager_command.to = NULL;
    config.cluster_manager_command.from_user = NULL;
    config.cluster_manager_command.from_pass = NULL;
    config.cluster_manager_command.from_askpass = 0;
    config.cluster_manager_command.weight = NULL;
    config.cluster_manager_command.weight_argc = 0;
    config.cluster_manager_command.slots = 0;
    config.cluster_manager_command.timeout = CLUSTER_MANAGER_MIGRATE_TIMEOUT;
    config.cluster_manager_command.pipeline = CLUSTER_MANAGER_MIGRATE_PIPELINE;
    config.cluster_manager_command.threshold = CLUSTER_MANAGER_REBALANCE_THRESHOLD;
    config.cluster_manager_command.backup_dir = NULL;
    pref.hints = 1;

    spectrum_palette = spectrum_palette_color;
    spectrum_palette_size = spectrum_palette_color_size;

    if (!isatty(fileno(stdout)) && (getenv("FAKETTY") == NULL)) {
        config.output = OUTPUT_RAW;
        config.push_output = 0;
    } else {
        config.output = OUTPUT_STANDARD;
        config.push_output = 1;
    }
    config.mb_delim = sdsnew("\n");
    config.cmd_delim = sdsnew("\n");

    firstarg = parseOptions(argc, argv);
    argc -= firstarg;
    argv += firstarg;

    parseEnv();

    if (config.askpass) {
        config.conn_info.auth = askPassword("Please input password: ");
    }

    if (config.cluster_manager_command.from_askpass) {
        config.cluster_manager_command.from_pass = askPassword("Please input import source node password: ");
    }

#ifdef USE_OPENSSL
    if (config.tls) {
        cliSecureInit();
    }
#endif

    gettimeofday(&tv, NULL);
    init_genrand64(((long long)tv.tv_sec * 1000000 + tv.tv_usec) ^ getpid());

    /* Cluster Manager mode */
    if (CLUSTER_MANAGER_MODE()) {
        clusterManagerCommandProc *proc = validateClusterManagerCommand();
        if (!proc) {
            exit(1);
        }
        clusterManagerMode(proc);
    }

    /* Latency mode */
    if (config.latency_mode) {
        if (cliConnect(0) == REDIS_ERR) exit(1);
        latencyMode();
    }

    /* Latency distribution mode */
    if (config.latency_dist_mode) {
        if (cliConnect(0) == REDIS_ERR) exit(1);
        latencyDistMode();
    }

    /* Replica mode */
    if (config.replica_mode) {
        if (cliConnect(0) == REDIS_ERR) exit(1);
        sendCapa();
        sendReplconf("rdb-filter-only", "");
        replicaMode(1);
    }

    /* Get RDB/functions mode. */
    if (config.getrdb_mode || config.get_functions_rdb_mode) {
        if (cliConnect(0) == REDIS_ERR) exit(1);
        sendCapa();
        sendRdbOnly();
        if (config.get_functions_rdb_mode && !sendReplconf("rdb-filter-only", "functions")) {
            fprintf(stderr, "Failed requesting functions only RDB from server, aborting\n");
            exit(1);
        }
        getRDB(NULL);
    }

    /* Pipe mode */
    if (config.pipe_mode) {
        if (cliConnect(0) == REDIS_ERR) exit(1);
        pipeMode();
    }

    /* Find big keys */
    if (config.bigkeys) {
        if (cliConnect(0) == REDIS_ERR) exit(1);
        findBigKeys(0, 0);
    }

    /* Find large keys */
    if (config.memkeys) {
        if (cliConnect(0) == REDIS_ERR) exit(1);
        findBigKeys(1, config.memkeys_samples);
    }

    /* Find hot keys */
    if (config.hotkeys) {
        if (cliConnect(0) == REDIS_ERR) exit(1);
        findHotKeys();
    }

    /* Stat mode */
    if (config.stat_mode) {
        if (cliConnect(0) == REDIS_ERR) exit(1);
        if (config.interval == 0) config.interval = 1000000;
        statMode();
    }

    /* Scan mode */
    if (config.scan_mode) {
        if (cliConnect(0) == REDIS_ERR) exit(1);
        scanMode();
    }

    /* LRU test mode */
    if (config.lru_test_mode) {
        if (cliConnect(0) == REDIS_ERR) exit(1);
        LRUTestMode();
    }

    /* Intrinsic latency mode */
    if (config.intrinsic_latency_mode) intrinsicLatencyMode();

    /* Print command-line hint for an input prefix string */
    if (config.test_hint) {
        testHint(config.test_hint);
    }
    /* Run test suite for command-line hints */
    if (config.test_hint_file) {
        testHintSuite(config.test_hint_file);
    }

    /* Start interactive mode when no command is provided */
    if (argc == 0 && !config.eval) {
        /* Ignore SIGPIPE in interactive mode to force a reconnect */
        signal(SIGPIPE, SIG_IGN);
        signal(SIGINT, sigIntHandler);

        /* Note that in repl mode we don't abort on connection error.
         * A new attempt will be performed for every command send. */
        cliConnect(0);
        repl();
    }

    /* Otherwise, we have some arguments to execute */
    if (config.eval) {
        if (cliConnect(0) != REDIS_OK) exit(1);
        return evalMode(argc, argv);
    } else {
        cliConnect(CC_QUIET);
        return noninteractive(argc, argv);
    }
}
